The origin of different spike and wave-like events (Hall et al 2017)

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Accession:235561
Acute In vitro models have revealed a great deal of information about mechanisms underlying many types of epileptiform activity. However, few examples exist that shed light on spike and wave (SpW) patterns of pathological activity. SpW are seen in many epilepsy syndromes, both generalised and focal, and manifest across the entire age spectrum. They are heterogeneous in terms of their severity, symptom burden and apparent anatomical origin (thalamic, neocortical or both), but any relationship between this heterogeneity and underlying pathology remains elusive. Here we demonstrate that physiological delta frequency rhythms act as an effective substrate to permit modelling of SpW of cortical origin and may help to address this issue. ..."
Reference:
1 . Hall SP, Traub RD, Adams NE, Cunningham MO, Schofield I, Jenkins AJ, Whittington MA (2018) Enhanced interlaminar excitation or reduced superficial layer inhibition in neocortex generates different spike-and-wave-like electrographic events in vitro. J Neurophysiol 119:49-61 [PubMed]
Model Information (Click on a link to find other models with that property)
Model Type: Realistic Network;
Brain Region(s)/Organism: Neocortex; Thalamus;
Cell Type(s): Thalamus geniculate nucleus/lateral principal GLU cell; Thalamus reticular nucleus GABA cell; Neocortex U1 L6 pyramidal corticalthalamic GLU cell; Neocortex U1 L2/6 pyramidal intratelencephalic GLU cell; Neocortex fast spiking (FS) interneuron; Neocortex spiking regular (RS) neuron; Neocortex spiking low threshold (LTS) neuron;
Channel(s): I Na,p; I Na,t; I L high threshold; I T low threshold; I A; I K; I M; I h; I K,Ca; I Calcium; I A, slow;
Gap Junctions: Gap junctions;
Receptor(s): GabaA; AMPA; NMDA;
Gene(s):
Transmitter(s):
Simulation Environment: FORTRAN;
Model Concept(s): Epilepsy;
Implementer(s): Traub, Roger D ;
Search NeuronDB for information about:  Thalamus geniculate nucleus/lateral principal GLU cell; Thalamus reticular nucleus GABA cell; Neocortex U1 L2/6 pyramidal intratelencephalic GLU cell; Neocortex U1 L6 pyramidal corticalthalamic GLU cell; GabaA; AMPA; NMDA; I Na,p; I Na,t; I L high threshold; I T low threshold; I A; I K; I M; I h; I K,Ca; I Calcium; I A, slow;
/
HallEtAl2017
readme.txt
dexptablebig_setup.f *
dexptablesmall_setup.f *
fnmda.f *
groucho_gapbld.f *
groucho_gapbld_mix.f *
integrate_deepaxaxx.f *
integrate_deepbaskx.f *
integrate_deepLTSx.f *
integrate_deepng.f *
integrate_nontuftRSXXB.f *
integrate_nrtxB.f *
integrate_spinstelldiegoxB.f *
integrate_supaxaxx.f *
integrate_supbaskx.f *
integrate_supLTSX.f *
integrate_supng.f *
integrate_suppyrFRBxPB.f *
integrate_suppyrRS.f *
integrate_suppyrRSXPB.f *
integrate_tcrxB.f *
integrate_tuftIBVx3B.f *
integrate_tuftRSXXB.f *
makefile *
otis_table_setup.f *
spikewaveS96.f
spikewaveS96.pdf
synaptic_map_construct.f *
                            
c 26 Feb. 2013, start with spikewaveR70, which Miles liked, alter synaptic inputs
c to nontuftRS as per spikewaveR73; then put integration routine for nontuftRS
c into main program, so as to be able to alter intrinsic conductances.

c 21 Feb. 2013, start with spikewave69.f, but incorporate suppyrRS integration
c routine into main file, so as to be able to alter intrinsic properties.

c 7 Dec. 2011, from deltaAIX108.f: for use with delta and nicotinic spike-wave,
c involving all types of cortical cells - see notebook figs from Miles, this date.
! 4 June 2009, from Buster's delta107.f - rework to run on 16 nodes.
! 27 Oct. 2006, add ability to modify Ih in tuftIB.
! 22 Oct. 2006, further modification to all GABA-B (if large enough in local
! population of cells) to shut off ectopics in tuftIB.
! 19 Oct. 2006, from interactB.f, has GABA-B, for use in delta oscillations.
c Last interactB data: INTERACTB30....
! 17 Sept. 2006: start with /interact/interact.f, and add neurogliaform cells:
! supng and deepng.  These cells make GABA-B IPSCs in cortical principal cells.
! In addition, nRT cells can make GABA-B IPSCs in each other and in TCR cells.
! Integration subroutines testable, and tidied up - see red lab notebook.

! 7 Nov. 2005: make suppyrRS & FRB axons Colbert/Pan.
! 24 Oct. 2005, take isoldeepVFOKM2.f and restore synaptic connections as in groucho84.f.
! To inactivate deep or superficial layers, try hyperpolarizing axons of respective cell
! populations.

! 22 Oct. 2005, start with isoldeepVFOKM2.f; use different tuftIB integration
! subroutine, allowing passage of a variable for shifting gKM rate functions.
! 31 Aug. 2005: in integration subroutine for tuftIB, VK relatively depolarized
! (in groucho it was -95 mV); AND scaling of gCaL depends on the cell.

! 29 July 2005, begin revising isoldeepVFO.f so that cells of a given type can
! be distributed across many nodes.

! Alter distal axon structure: assumption in groucho.f is that at most 1000 cells
! of any one cell type (27 July 2005); all runs of isoldeepVFO and isoldeepcut
! up to this point, with more than 1000 tuftIB cells, are therefore suspect.

! 14 June 2005, taken from isoldeep/isoldeep99.f; allows passing to tuftIB
! integration subroutine the relative shift of axonal gNa kinetics.
! 26 Jan. 2005: take Diego42.f & separate layers 5 & 6 from thalamus, and layers 
!  4 and 2/3; perhaps also block all NMDA in deep layers.
! reduce drive to nontuftRS
! pass parameters to regulate gK(AHP) & gNaP in tuftIB cells, and gKM and gKA
! 11 October 2004, modify diego.f and also integrate_nontuftRS.f in /diego so that
! nontuftRS_nFRB of the num_spinstell cells are FRB cells, as in layVtup.f.3Feb04.

! 15 August 2004: copy gutnick.f; use modified stellate cell as in /spinst/bryan.f;
! For study of spiny stellate response to thalamic stimulation, in full network.

! 25 Aug. 2004: necessary to explore TCR -> deep interneuron connectivity, so
! that deep interneurons fire very soon after TCR volley, e.g. make connections
! proximal and strong....

c 14 June 2004, version of groucho.f (from groucho94.f), with which, in this
c directory (gutnick) integrate_spinstell.f is modified: NMDA conductance is
c neither voltage nor Mg dependent.  c.f. Fleidervish et al. 1998 NEURON
c In addition, in PROGRAM GROUCHO, tau NMDA for these connections likely to
c be shortened.


c Cell types: superficial pyramidal RS; superficial pyramidal FRB;
c superficial basket; superficial axoaxonic; superficial LTS;
c spiny stellate; tufted deep IB; tufted deep RS; nontufted deep RS;
c deep basket; deep axoaxonic; deep LTS; thalamocortical relay (TCR);
c nucleus reticularis thalami (nRT).

               PROGRAM GROUCHO

! Reduce numbers of some non-deep cells, to speed things up
        PARAMETER (num_suppyrRS = 1000, num_suppyrFRB =  50,
     & num_supbask = 90, num_supaxax = 90, num_supLTS = 90,
!    & num_spinstell = 240, num_tuftIB = 500, num_tuftRS = 500,
!    & num_spinstell = 100, num_tuftIB = 800, num_tuftRS = 200, ! Diego unsure how many tuftRS there are
     & num_spinstell = 240, num_tuftIB =2000, num_tuftRS = 200, ! Diego unsure how many tuftRS there are
     & num_nontuftRS = 500, nontuftRS_nFRB =   2,
! Last nontuftRS_nFRB nontuftRS cells are FRB 
     & num_deepbask = 100, 
     & num_deepaxax = 100, num_deepLTS = 100, num_TCR = 100,
     & num_supng = 90, num_deepng = 100,
     & num_nRT = 100, num_allcells = 4950, num_celltypes = 16)

        PARAMETER (ncellspernode_suppyrRS = 250, 
     &    nodesfor_suppyrRS  = 4,
     &             ncellspernode_suppyrFRB=  50,
     &    nodesfor_suppyrFRB = 1,
     &             ncellspernode_supbask  =  90,
     &    nodesfor_supbask   = 1,
     &             ncellspernode_supaxax  =  90,
     &    nodesfor_supaxax   = 1,
     &             ncellspernode_supLTS   =  90,
     &    nodesfor_supLTS    = 1,
     &             ncellspernode_spinstell= 240,  
     &    nodesfor_spinstell = 1,
c    &             ncellspernode_tuftIB   = 250,
     &             ncellspernode_tuftIB   = 400,
c    &    nodesfor_tuftIB    = 8,
     &    nodesfor_tuftIB    = 5,
     &             ncellspernode_tuftRS   = 200,
     &    nodesfor_tuftRS    = 1,
     &             ncellspernode_nontuftRS= 250,  
     &    nodesfor_nontuftRS = 2,
     &             ncellspernode_deepbask = 100,
     &    nodesfor_deepbask  = 1,
     &             ncellspernode_deepaxax = 100,
     &    nodesfor_deepaxax  = 1,
     &             ncellspernode_deepLTS  = 100, 
     &    nodesfor_deepLTS   = 1,
     &             ncellspernode_TCR      = 100,
     &    nodesfor_TCR       = 1,
     &             ncellspernode_nRT      = 100,            
     &    nodesfor_nRT       = 1,
     &             ncellspernode_supng    =  90,
     &    nodesfor_supng     = 1,
     &             ncellspernode_deepng   = 100,
     &    nodesfor_deepng    = 1)

c       PARAMETER (numnodes = 27)  ! Check manually for consistency.
        PARAMETER (numnodes = 24)  ! Check manually for consistency.
c       PARAMETER (maxcellspernode = 250)
        PARAMETER (maxcellspernode = 400)
            

        PARAMETER (numcomp_suppyrRS   = 74,
     &             numcomp_suppyrFRB  = 74,
     &             numcomp_supbask    = 59,
     &             numcomp_supaxax    = 59,
     &             numcomp_supLTS     = 59,
     &             numcomp_spinstell  = 59,
     &             numcomp_tuftIB     = 61,
     &             numcomp_tuftRS     = 61,
     &             numcomp_nontuftRS  = 50,
     &             numcomp_deepbask   = 59,
     &             numcomp_deepaxax   = 59,
     &             numcomp_deepLTS    = 59,
     &             numcomp_TCR        =137,
     &             numcomp_nRT        = 59,
     &             numcomp_supng      = 59,
     &             numcomp_deepng     = 59)

        PARAMETER (num_suppyrRS_to_suppyrRS = 50,
     &   num_suppyrRS_to_suppyrFRB = 50,
     &   num_suppyrRS_to_supbask   = 90, ! note
     &   num_suppyrRS_to_supaxax   = 90, ! note
     &   num_suppyrRS_to_supLTS    = 90, ! note
     &   num_suppyrRS_to_supng     = 90, ! note
!    &   num_suppyrRS_to_spinstell = 30,
     &   num_suppyrRS_to_spinstell =  3, ! make small, per Thomson & Bannister
!    &   num_suppyrRS_to_tuftIB    = 30,
     &   num_suppyrRS_to_tuftIB    = 60, ! big per Thomson & Bannister
!    &   num_suppyrRS_to_tuftRS    = 30,
     &   num_suppyrRS_to_tuftRS    = 60, ! big per Thomson & Bannister

!    &   num_suppyrRS_to_deepbask  = 30,
     &   num_suppyrRS_to_deepbask  = 10, ! 16 Nov. 2004: Alex T says density of
! connections from sup pyrs to deep interneurons not known, although exist: try smaller value
!    &   num_suppyrRS_to_deepaxax  = 30,
     &   num_suppyrRS_to_deepaxax  = 10, ! see above
!    &   num_suppyrRS_to_deepLTS   = 30,
     &   num_suppyrRS_to_deepLTS   = 10, ! see above
! No suppyrRS to deepng

!    &   num_suppyrRS_to_nontuftRS = 30,
     &   num_suppyrRS_to_nontuftRS =  3, ! small per Thomson & Bannister
     &   num_suppyrFRB_to_suppyrRS = 5,
     &   num_suppyrFRB_to_suppyrFRB= 5,
     &   num_suppyrFRB_to_supbask  = 5,
     &   num_suppyrFRB_to_supaxax  = 5,
     &   num_suppyrFRB_to_supLTS   = 5,
     &   num_suppyrFRB_to_supng    = 5,
!    &   num_suppyrFRB_to_spinstell= 3,
     &   num_suppyrFRB_to_spinstell= 1, ! make small, per Thomson & Bannister
     &   num_suppyrFRB_to_tuftIB   = 3,
     &   num_suppyrFRB_to_tuftRS   = 3,
!    &   num_suppyrFRB_to_deepbask = 3,
     &   num_suppyrFRB_to_deepbask = 1, ! see note above with suppyrRS_to_deepbask
!    &   num_suppyrFRB_to_deepaxax = 3,
     &   num_suppyrFRB_to_deepaxax = 1, ! see note above
!    &   num_suppyrFRB_to_deepLTS  = 3,
     &   num_suppyrFRB_to_deepLTS  = 1, ! see note above
! No suppyrFRB to deepng
!    &   num_suppyrFRB_to_nontuftRS= 3)
     &   num_suppyrFRB_to_nontuftRS= 1) ! small per Thomson & Bannister
        PARAMETER
     &  (num_supbask_to_suppyrRS   = 20,
     &   num_supbask_to_suppyrFRB  = 20,
     &   num_supbask_to_supbask    = 20,
     &   num_supbask_to_supaxax    = 20,
     &   num_supbask_to_supLTS     = 20,
     &   num_supbask_to_supng      = 20,
     &   num_supbask_to_spinstell  = 20,

     &   num_supaxax_to_suppyrRS   = 20, ! note
     &   num_supaxax_to_suppyrFRB  = 20,  ! note
     &   num_supaxax_to_spinstell  = 5,
     &   num_supaxax_to_tuftIB     = 5,
     &   num_supaxax_to_tuftRS     = 5,
     &   num_supaxax_to_nontuftRS  = 5,

     &   num_supLTS_to_suppyrRS    = 20,
     &   num_supLTS_to_suppyrFRB   = 20,
     &   num_supLTS_to_supbask     = 20,
     &   num_supLTS_to_supaxax     = 20,
     &   num_supLTS_to_supLTS      = 20,
     &   num_supLTS_to_spinstell   = 20,
     &   num_supLTS_to_tuftIB      = 20)

        PARAMETER
     &  (num_supng_to_suppyrRS     = 20,
     &   num_supng_to_suppyrFRB    = 20,
     &   num_supng_to_nontuftRS    = 20,
     &   num_supng_to_tuftIB       = 20,
     &   num_supng_to_tuftRS       = 20,
     &   num_supng_to_supng        = 10,
     &   num_supng_to_supbask      = 10)

        PARAMETER
     &  (num_supLTS_to_tuftRS      = 20,
     &   num_supLTS_to_deepbask    = 20,
     &   num_supLTS_to_deepaxax    = 20,
     &   num_supLTS_to_deepLTS     = 20,
     &   num_supLTS_to_nontuftRS   = 20,

     &   num_spinstell_to_suppyrRS = 20,
     &   num_spinstell_to_suppyrFRB= 20,
     &   num_spinstell_to_supbask  = 20,
     &   num_spinstell_to_supaxax  = 20,
     &   num_spinstell_to_supLTS   = 20,
     &   num_spinstell_to_spinstell= 30,
     &   num_spinstell_to_tuftIB   = 20,
     &   num_spinstell_to_tuftRS   = 20,
     &   num_spinstell_to_deepbask = 20,
     &   num_spinstell_to_deepaxax = 20,
     &   num_spinstell_to_deepLTS  = 20,
     &   num_spinstell_to_deepng   = 20,
     &   num_spinstell_to_nontuftRS= 20,

     &   num_tuftIB_to_suppyrRS    = 20,
c    &   num_tuftIB_to_suppyrRS    =  2, ! small per Thomson & Bannister
!    &   num_tuftIB_to_suppyrFRB   = 20,
     &   num_tuftIB_to_suppyrFRB   =  2, ! small per Thomson & Bannister
!    &   num_tuftIB_to_supbask     = 20)
     &   num_tuftIB_to_supbask     = 10) ! 17 Nov. 2004, try smaller value

        PARAMETER
!    &  (num_tuftIB_to_supaxax     = 20,
     &  (num_tuftIB_to_supaxax     = 10, ! 17 Nov. 2004, try smaller value
!    &   num_tuftIB_to_supLTS      = 20,
     &   num_tuftIB_to_supLTS      = 10, ! 17 Nov. 2004, try smaller value
     &   num_tuftIB_to_spinstell   = 20,
     &   num_tuftIB_to_tuftIB      = 50,
     &   num_tuftIB_to_tuftRS      = 20,
     &   num_tuftIB_to_deepbask    = 20,
     &   num_tuftIB_to_deepaxax    = 20,
     &   num_tuftIB_to_deepLTS     = 20,
c    &   num_tuftIB_to_deepng      = 20,
c    &   num_tuftIB_to_deepng      = 30,
     &   num_tuftIB_to_deepng      = 50,
     &   num_tuftIB_to_nontuftRS   = 20,

     &   num_tuftRS_to_suppyrRS    = 20,
c    &   num_tuftRS_to_suppyrRS    =  2, ! small per Thomson & Bannister
!    &   num_tuftRS_to_suppyrFRB   = 20,
     &   num_tuftRS_to_suppyrFRB   =  2, ! small per Thomson & Bannister
     &   num_tuftRS_to_supbask     = 20,
     &   num_tuftRS_to_supaxax     = 20,
     &   num_tuftRS_to_supLTS      = 20,
     &   num_tuftRS_to_spinstell   = 20,
     &   num_tuftRS_to_tuftIB      = 20,
     &   num_tuftRS_to_tuftRS      = 10,
     &   num_tuftRS_to_deepbask    = 20,
     &   num_tuftRS_to_deepaxax    = 20,
     &   num_tuftRS_to_deepLTS     = 20,
     &   num_tuftRS_to_deepng      = 20,
     &   num_tuftRS_to_nontuftRS   = 20)

        PARAMETER
     &  (num_deepbask_to_spinstell = 20,
     &   num_deepbask_to_tuftIB    = 20,
     &   num_deepbask_to_tuftRS    = 20,
     &   num_deepbask_to_deepbask  = 20,
     &   num_deepbask_to_deepaxax  = 20,
     &   num_deepbask_to_deepLTS   = 20,
     &   num_deepbask_to_deepng    = 20,
     &   num_deepbask_to_nontuftRS = 20,

     &   num_deepaxax_to_suppyrRS  =  5,
     &   num_deepaxax_to_suppyrFRB =  5,
     &   num_deepaxax_to_spinstell =  5,
     &   num_deepaxax_to_tuftIB    =  5,
     &   num_deepaxax_to_tuftRS    =  5,
     &   num_deepaxax_to_nontuftRS =  5,

     &   num_deepLTS_to_suppyrRS   = 10)
        PARAMETER
     &  (num_deepLTS_to_suppyrFRB  = 10,
     &   num_deepLTS_to_supbask    = 10,
     &   num_deepLTS_to_supaxax    = 10,
     &   num_deepLTS_to_supLTS     = 10,
     &   num_deepLTS_to_spinstell  = 20,
     &   num_deepLTS_to_tuftIB     = 20,
     &   num_deepLTS_to_tuftRS     = 20,
     &   num_deepLTS_to_deepbask   = 20,
     &   num_deepLTS_to_deepaxax   = 20,
     &   num_deepLTS_to_deepLTS    = 20,
     &   num_deepLTS_to_nontuftRS  = 20)

        PARAMETER
     &  (num_deepng_to_tuftIB      = 20,
     &   num_deepng_to_tuftRS      = 20,
     &   num_deepng_to_nontuftRS   = 20,
     &   num_deepng_to_spinstell   = 20,
     &   num_deepng_to_deepng      = 10,
     &   num_deepng_to_deepbask    = 10,

     &   num_TCR_to_suppyrRS       = 10,
     &   num_TCR_to_suppyrFRB      = 10,
     &   num_TCR_to_supbask        = 10,
     &   num_TCR_to_supaxax        = 10,
     &   num_TCR_to_supng          = 10,
!    &   num_TCR_to_spinstell      = 10,
     &   num_TCR_to_spinstell      = 20,
     &   num_TCR_to_tuftIB         = 10,
     &   num_TCR_to_tuftRS         = 10,
!    &   num_TCR_to_deepbask       = 10,
     &   num_TCR_to_deepbask       = 20,
     &   num_TCR_to_deepaxax       = 10,
     &   num_TCR_to_deepng         = 10,
     &   num_TCR_to_nRT            = 25, ! note
     &   num_TCR_to_nontuftRS      = 10,

     &   num_nRT_to_TCR            = 15, ! note
     &   num_nRT_to_nRT            = 10)
        PARAMETER
     &  (num_nontuftRS_to_suppyrRS = 25,
     &   num_nontuftRS_to_suppyrFRB= 10,
     &   num_nontuftRS_to_supbask  = 10,
     &   num_nontuftRS_to_supaxax  = 10,
     &   num_nontuftRS_to_supLTS   = 10,
     &   num_nontuftRS_to_spinstell= 10,
     &   num_nontuftRS_to_tuftIB   = 10,
     &   num_nontuftRS_to_tuftRS   = 10,
     &   num_nontuftRS_to_deepbask = 10,
     &   num_nontuftRS_to_deepaxax = 10,
     &   num_nontuftRS_to_deepLTS  = 10,
     &   num_nontuftRS_to_deepng   = 10,
     &   num_nontuftRS_to_TCR      = 20,
     &   num_nontuftRS_to_nRT      = 20,
     &   num_nontuftRS_to_nontuftRS= 40)

c Begin definition of number of compartments that can be
c contacted for each type of synaptic connection.
        PARAMETER (ncompallow_suppyrRS_to_suppyrRS = 36,
     &   ncompallow_suppyrRS_to_suppyrFRB = 36,
     &   ncompallow_suppyrRS_to_supbask   = 24,
     &   ncompallow_suppyrRS_to_supaxax   = 24,
     &   ncompallow_suppyrRS_to_supLTS    = 24,
     &   ncompallow_suppyrRS_to_supng     = 52,
     &   ncompallow_suppyrRS_to_spinstell = 24,
     &   ncompallow_suppyrRS_to_tuftIB    =  8,
     &   ncompallow_suppyrRS_to_tuftRS    =  8,
     &   ncompallow_suppyrRS_to_deepbask  = 24,
     &   ncompallow_suppyrRS_to_deepaxax  = 24,
     &   ncompallow_suppyrRS_to_deepLTS   = 24,
     &   ncompallow_suppyrRS_to_nontuftRS =  7)

        PARAMETER (ncompallow_suppyrFRB_to_suppyrRS = 36,
     &   ncompallow_suppyrFRB_to_suppyrFRB = 36,
     &   ncompallow_suppyrFRB_to_supbask   = 24,
     &   ncompallow_suppyrFRB_to_supaxax   = 24,
     &   ncompallow_suppyrFRB_to_supLTS    = 24,
     &   ncompallow_suppyrFRB_to_supng     = 52,
     &   ncompallow_suppyrFRB_to_spinstell = 24,
     &   ncompallow_suppyrFRB_to_tuftIB    =  8,
     &   ncompallow_suppyrFRB_to_tuftRS    =  8,
     &   ncompallow_suppyrFRB_to_deepbask  = 24,
     &   ncompallow_suppyrFRB_to_deepaxax  = 24,
     &   ncompallow_suppyrFRB_to_deepLTS   = 24,
     &   ncompallow_suppyrFRB_to_nontuftRS =  7)

        PARAMETER (ncompallow_supbask_to_suppyrRS   = 11,
     &   ncompallow_supbask_to_suppyrFRB   = 11,
     &   ncompallow_supbask_to_supbask     = 24,
     &   ncompallow_supbask_to_supng       = 4, 
     &   ncompallow_supbask_to_supaxax     = 24,
     &   ncompallow_supbask_to_supLTS      = 24,
     &   ncompallow_supbask_to_spinstell   =  5)

        PARAMETER (ncompallow_supLTS_to_suppyrRS    = 53,
     &   ncompallow_supLTS_to_suppyrFRB    = 53,
     &   ncompallow_supLTS_to_supbask      = 40,
     &   ncompallow_supLTS_to_supaxax      = 40,
     &   ncompallow_supLTS_to_supLTS       = 40,
     &   ncompallow_supLTS_to_spinstell    = 40,
     &   ncompallow_supLTS_to_tuftIB       = 40,
     &   ncompallow_supLTS_to_tuftRS       = 40,
     &   ncompallow_supLTS_to_deepbask     = 20,
     &   ncompallow_supLTS_to_deepaxax     = 20,
     &   ncompallow_supLTS_to_deepLTS      = 20,
     &   ncompallow_supLTS_to_nontuftRS    = 29)

        PARAMETER (ncompallow_supng_to_suppyrRS = 64,
     &   ncompallow_supng_to_suppyrFRB     = 64,
     &   ncompallow_supng_to_nontuftRS     =  5,
     &   ncompallow_supng_to_tuftIB        = 14,
     &   ncompallow_supng_to_tuftRS        = 14,
     &   ncompallow_supng_to_supng         =  4,
     &   ncompallow_supng_to_supbask       =  4)

        PARAMETER (ncompallow_spinstell_to_suppyrRS = 24,
     &   ncompallow_spinstell_to_suppyrFRB = 24,
     &   ncompallow_spinstell_to_supbask   = 24,
     &   ncompallow_spinstell_to_supaxax   = 24,
     &   ncompallow_spinstell_to_supLTS    = 24,
     &   ncompallow_spinstell_to_spinstell = 24,
     &   ncompallow_spinstell_to_tuftIB    = 12,
     &   ncompallow_spinstell_to_tuftRS    = 12,
     &   ncompallow_spinstell_to_deepbask  = 24,
     &   ncompallow_spinstell_to_deepaxax  = 24,
     &   ncompallow_spinstell_to_deepLTS   = 24,
     &   ncompallow_spinstell_to_deepng    = 52,
     &   ncompallow_spinstell_to_nontuftRS =  5)

        PARAMETER (ncompallow_tuftIB_to_suppyrRS   = 13,
     &   ncompallow_tuftIB_to_suppyrFRB    = 13,
     &   ncompallow_tuftIB_to_supbask      = 24,
     &   ncompallow_tuftIB_to_supaxax      = 24,
     &   ncompallow_tuftIB_to_supLTS       = 24,
     &   ncompallow_tuftIB_to_spinstell    = 24,
     &   ncompallow_tuftIB_to_tuftIB       = 46,
     &   ncompallow_tuftIB_to_tuftRS       = 46,
     &   ncompallow_tuftIB_to_deepbask     = 24,
     &   ncompallow_tuftIB_to_deepaxax     = 24,
     &   ncompallow_tuftIB_to_deepLTS      = 24,
     &   ncompallow_tuftIB_to_deepng       = 52,
     &   ncompallow_tuftIB_to_nontuftRS    = 43)

        PARAMETER (ncompallow_tuftRS_to_suppyrRS   = 13,
     &   ncompallow_tuftRS_to_suppyrFRB    = 13,
     &   ncompallow_tuftRS_to_supbask      = 24,
     &   ncompallow_tuftRS_to_supaxax      = 24,
     &   ncompallow_tuftRS_to_supLTS       = 24,
     &   ncompallow_tuftRS_to_spinstell    = 24,
     &   ncompallow_tuftRS_to_tuftIB       = 46,
     &   ncompallow_tuftRS_to_tuftRS       = 46,
     &   ncompallow_tuftRS_to_deepbask     = 24,
     &   ncompallow_tuftRS_to_deepaxax     = 24,
     &   ncompallow_tuftRS_to_deepLTS      = 24,
     &   ncompallow_tuftRS_to_deepng       = 52,
     &   ncompallow_tuftRS_to_nontuftRS    = 43)

        PARAMETER (ncompallow_deepbask_to_spinstell = 5, 
     &   ncompallow_deepbask_to_tuftIB     =  8,
     &   ncompallow_deepbask_to_tuftRS     =  8,
     &   ncompallow_deepbask_to_deepbask   = 24,
     &   ncompallow_deepbask_to_deepaxax   = 24,
     &   ncompallow_deepbask_to_deepLTS    = 24,
     &   ncompallow_deepbask_to_deepng     =  4,
     &   ncompallow_deepbask_to_nontuftRS  =  8)

        PARAMETER (ncompallow_deepLTS_to_suppyrRS = 53,
     &   ncompallow_deepLTS_to_suppyrFRB   = 53,
     &   ncompallow_deepLTS_to_supbask     = 20,
     &   ncompallow_deepLTS_to_supaxax     = 20,
     &   ncompallow_deepLTS_to_supLTS      = 20,
     &   ncompallow_deepLTS_to_spinstell   = 40,
     &   ncompallow_deepLTS_to_tuftIB      = 40,
     &   ncompallow_deepLTS_to_tuftRS      = 40,
     &   ncompallow_deepLTS_to_deepbask    = 40,
     &   ncompallow_deepLTS_to_deepaxax    = 40,
     &   ncompallow_deepLTS_to_deepLTS     = 40,
     &   ncompallow_deepLTS_to_nontuftRS   = 29)

        PARAMETER (ncompallow_deepng_to_tuftIB = 33,
     &   ncompallow_deepng_to_tuftRS    = 33,
     &   ncompallow_deepng_to_nontuftRS = 33,
     &   ncompallow_deepng_to_spinstell = 52,
     &   ncompallow_deepng_to_deepng    =  4,
     &   ncompallow_deepng_to_deepbask  = 52)

        PARAMETER (ncompallow_TCR_to_suppyrRS = 24,
     &   ncompallow_TCR_to_suppyrFRB    = 24,
     &   ncompallow_TCR_to_supbask      = 12,
     &   ncompallow_TCR_to_supaxax      = 12,
     &   ncompallow_TCR_to_supng        = 52,
     &   ncompallow_TCR_to_spinstell    = 52,
     &   ncompallow_TCR_to_tuftIB       =  9,
     &   ncompallow_TCR_to_tuftRS       =  9,
!    &   ncompallow_TCR_to_deepbask     = 12,
     &   ncompallow_TCR_to_deepbask     =  5, ! make them proximal
!    &   ncompallow_TCR_to_deepaxax     = 12,
     &   ncompallow_TCR_to_deepaxax     =  5, ! make them proximal
     &   ncompallow_TCR_to_deepng       = 52, 
     &   ncompallow_TCR_to_nRT          = 12,
     &   ncompallow_TCR_to_nontuftRS    =  5)

        PARAMETER (ncompallow_nRT_to_TCR  = 11,
     &   ncompallow_nRT_to_nRT = 53)

        PARAMETER (ncompallow_nontuftRS_to_suppyrRS = 4,
     &    ncompallow_nontuftRS_to_suppyrFRB =  4,
     &    ncompallow_nontuftRS_to_supbask   = 24,
     &    ncompallow_nontuftRS_to_supaxax   = 24,
     &    ncompallow_nontuftRS_to_supLTS    = 24,
     &    ncompallow_nontuftRS_to_spinstell = 24,
     &    ncompallow_nontuftRS_to_tuftIB    = 46,
     &    ncompallow_nontuftRS_to_tuftRS    = 46,
     &    ncompallow_nontuftRS_to_deepbask  = 24,
     &    ncompallow_nontuftRS_to_deepaxax  = 24,
     &    ncompallow_nontuftRS_to_deepLTS   = 24,
     &    ncompallow_nontuftRS_to_deepng    = 52,
     &    ncompallow_nontuftRS_to_TCR       = 90,
     &    ncompallow_nontuftRS_to_nRT       = 12,
     &    ncompallow_nontuftRS_to_nontuftRS = 43)
c End definition of number of allowed compartments that
c can be contacted for each sort of connection

c Note that gj form only between cells of a given type,
c  except suppyrRS/suppyrFRB & tuftIB/tuftRS
c gj/cell = 2 x total gj / # cells
c for proportions, see /home/traub/supergj/tests.f
c      integer, parameter :: totaxgj_suppyrRS =  722 ! Before 19 Nov. 2005
c      integer, parameter :: totaxgj_suppyrFRB =   4 ! Before 19 Nov. 2005
c      integer, parameter :: totaxgj_suppyr    =  74 ! Before 19 Nov. 2005
c      integer, parameter :: totaxgj_suppyrRS =  900
       integer, parameter :: totaxgj_suppyrRS = 1500
       integer, parameter :: totaxgj_suppyrFRB =   5 
       integer, parameter :: totaxgj_suppyr    =  95 
! totaxgj_suppyr = number of "mixed" gj between RS suppyr
! (1st col. of table) and FRB suppyr (3rd col. of table) cells
       integer, parameter :: totSDgj_supbask   = 200 
       integer, parameter :: totSDgj_supaxax   =   0 
       integer, parameter :: totSDgj_supLTS    = 200 
!      integer, parameter :: totaxgj_spinstell = 240 
       integer, parameter :: totaxgj_spinstell = 180 ! keep small: axons now very excitable 
!      integer, parameter :: totaxgj_tuftIB    = 640 ! was 350 in diego42; ? bring above percoln.? 
c      integer, parameter :: totaxgj_tuftIB    = 800 ! was 350 in diego42; ? bring above percoln.? 
       integer, parameter :: totaxgj_tuftIB    =2000 ! was 350 in diego42; ? bring above percoln.? 
       integer, parameter :: totaxgj_tuftRS    = 160 ! was 350 in diego42 
c      integer, parameter :: totaxgj_tuftRS    = 100 ! was 350 in diego42 
!      integer, parameter :: totaxgj_tuft      = 350 
c      integer, parameter :: totaxgj_tuft      =  10 ! decr. antidr. bursts in IB: diego series 
       integer, parameter :: totaxgj_tuft      =  50 ! decr. antidr. bursts in IB 
! totaxgj_tuft for mixed gj between tuftIB (1st) and tuftRS (next)
       integer, parameter :: totaxgj_nontuftRS = 500 
       integer, parameter :: totSDgj_deepbask  = 250 
       integer, parameter :: totSDgj_deepaxax  =   0 
       integer, parameter :: totSDgj_deepLTS   = 250 
       integer, parameter :: totaxgj_TCR       = 100  
       integer, parameter :: totSDgj_nRT       = 250
       integer, parameter :: totSDgj_supng     = 250
       integer, parameter :: totSDgj_deepng    = 250
c Note: no gj between axoaxonic cells.

c Define number of compartments on a cell where a gj might form
       integer, parameter :: num_axgjcompallow_suppyrRS = 1
       integer, parameter :: num_axgjcompallow_suppyrFRB= 1
       integer, parameter :: num_SDgjcompallow_supbask  = 8
       integer, parameter :: num_SDgjcompallow_supng    = 8
       integer, parameter :: num_SDgjcompallow_supLTS   = 8
       integer, parameter :: num_axgjcompallow_spinstell= 1
       integer, parameter :: num_axgjcompallow_tuftIB   = 1
       integer, parameter :: num_axgjcompallow_tuftRS   = 1
       integer, parameter :: num_axgjcompallow_nontuftRS= 1
       integer, parameter :: num_SDgjcompallow_deepbask = 8
       integer, parameter :: num_SDgjcompallow_deepng   = 8
       integer, parameter :: num_SDgjcompallow_deepLTS  = 8
       integer, parameter :: num_axgjcompallow_TCR      = 1
       integer, parameter :: num_SDgjcompallow_nRT      = 8

c Define gap junction conductances.
c      double precision, parameter :: gapcon_suppyrRS  = 3.d-3
!      double precision, parameter :: gapcon_suppyrRS  = 6.0d-3
       double precision, parameter :: gapcon_suppyrRS  = 3.0d-3
!      double precision, parameter :: gapcon_suppyrRS  = 0.d-3 ! to see if superf. lay. can follow 40 Hz
c      double precision, parameter :: gapcon_suppyrFRB = 3.d-3
!      double precision, parameter :: gapcon_suppyrFRB = 6.0d-3
       double precision, parameter :: gapcon_suppyrFRB = 3.0d-3
!      double precision, parameter :: gapcon_suppyrFRB = 0.d-3 ! to see if superf. lay. can follow 40 Hz
       double precision, parameter :: gapcon_supbask   = 1.d-3
       double precision, parameter :: gapcon_supng     = 0.5d-3
       double precision, parameter :: gapcon_supaxax   = 0.d-3
       double precision, parameter :: gapcon_supLTS    = 1.d-3

       double precision, parameter :: gapcon_spinstell = 3.d-3
!      double precision, parameter :: gapcon_spinstell = 2.d-3
!      double precision, parameter :: gapcon_spinstell = 0.d-3 ! to see if ctx follows 40 Hz from thal.

       double precision, parameter :: gapcon_tuftIB    = 4.d-3
c      double precision, parameter :: gapcon_tuftIB    = 3.0d-3
c      double precision, parameter :: gapcon_tuftIB    = 1.0d-3 ! to suppress gj-delta in CCh conditions, 13 May 2007
!      double precision, parameter :: gapcon_tuftIB    = 0.d-3 ! to decr. antidr. bursting
c      double precision, parameter :: gapcon_tuftRS    = 4.d-3
       double precision, parameter :: gapcon_tuftRS    = 1.d-3
!      double precision, parameter :: gapcon_tuftRS    = 0.d-3 ! now follow 40 Hz?
c      double precision, parameter :: gapcon_nontuftRS = 4.d-3
       double precision, parameter :: gapcon_nontuftRS = 0.d-3 ! to abolish VFO in lay. 6
       double precision, parameter :: gapcon_deepbask  = 1.d-3
!      double precision, parameter :: gapcon_deepbask  = 0.d-3
       double precision, parameter :: gapcon_deepng    = 0.5d-3
       double precision, parameter :: gapcon_deepaxax  = 0.d-3
       double precision, parameter :: gapcon_deepLTS   = 1.d-3
!      double precision, parameter :: gapcon_deepLTS   = 0.d-3
!      double precision, parameter :: gapcon_TCR       = 3.d-3
       double precision, parameter :: gapcon_TCR       = 0.d-3
c      double precision, parameter :: gapcon_nRT       = 1.d-3
       double precision, parameter :: gapcon_nRT       = 0.4d-3

! Parameters for scaling tuftIB conductances
       double precision, parameter :: scale_tuftIB_gAR  =1.0d0
c      double precision, parameter :: scale_tuftIB_gKAHP=0.50d0 ! this value in isoldeep99.f
c      double precision, parameter :: scale_tuftIB_gKAHP=1.00d0 ! this value isoldeep80.f
c      double precision, parameter :: scale_tuftIB_gKAHP=0.10d0 ! used in delta32
       double precision, parameter :: scale_tuftIB_gKAHP=0.00d0 ! used in delta32
c      double precision, parameter :: scale_tuftIB_gKAHP=2.00d0
c      double precision, parameter :: scale_tuftIB_gNaP =1.0d0 ! 25 Mar. 2005, define below
c      double precision, parameter :: scale_tuftIB_gKM  =1.0d0 ! 10 Feb. 2005, this one defined below
       double precision, parameter :: scale_tuftIB_gKA  =1.0d0
c      double precision, parameter :: scale_tuftIB_gKC  =0.1d0 ! this value in isoldeep99.f
       double precision, parameter :: scale_tuftIB_gKC  =1.0d0 ! this value in isoldeep80.f
c      double precision, parameter :: scale_tuftIB_gCaL =0.7d0 ! define below



c Assorted parameters
         double precision, parameter :: dt = 0.002d0
c        double precision, parameter :: Mg = 1.50
         double precision, parameter :: Mg = 1.00 ! for NMDA-dependent CCh delta, try lower Mg
! Castro-Alamancos J Physiol, disinhib. neocortex in vitro, uses
! Mg = 1.3
         double precision, parameter :: NMDA_saturation_fact
!    &                                   = 5.d0
     &                                   = 80.d0
c NMDA conductance developed on one postsynaptic compartment,
c from one type of presynaptic cell, can be at most this
c factor x unitary conductance
c UNFORTUNATELY, with this scheme,if one NMDA cond. set to 0
c on a cell type, all NMDA conductances will be forced to 0
c on that cell type...

       double precision, parameter :: thal_cort_delay = 1.d0
       double precision, parameter :: cort_thal_delay = 5.d0
       integer, parameter :: how_often = 50
! how_often defines how many time steps between synaptic conductance
! updates, and between broadcastings of axonal voltages.
       double precision, parameter :: axon_refrac_time = 1.5d0

c For these ectopic rate parameters, assume noisepe checked
c every 200 time steps = 0.4 ms = 1./2.5 ms
      double precision, parameter :: noisepe_suppyrRS   =
c    &      0.d0 
     &            1.d0 / (2.5d0 * 1000.d0) ! USUAL
c    &            1.d0 / (2.5d0 * 10000.d0) 
      double precision, parameter :: noisepe_suppyrFRB  =
     &            1.d0 / (2.5d0 * 1000.d0) ! USUAL
c    &            1.d0 / (2.5d0 * 10000.d0)
c    &      0.d0 
      double precision, parameter :: noisepe_spinstell  =
     &            1.d0 / (2.5d0 * 1000.d0)
! Note that noisepe_tuftIB will be time-dependent, and sensitive
! to total average GABA-B conductance in cells on each node
      double precision, parameter :: noisepe_tuftIB_save     =
c    &            1.d0 / (2.5d0 * 5000.d0)
c    &            1.d0 / (2.5d0 * 1000.d0)
     &            1.d0 / (2.5d0 * 10000.d0)
c    &            1.d0 / (2.5d0 *  250.d0) ! 29 March 2005
      double precision, parameter :: noisepe_tuftRS_save =
c this one also will be time_dependent
c    &            1.d0 / (2.5d0 * 1000.d0)
     &            1.d0 / (2.5d0 * 10000.d0)
      double precision, parameter :: noisepe_nontuftRS  =
c    &            1.d0 / (2.5d0 * 1000.d0)
     &            0.d0 / (2.5d0 * 1000.d0)
      double precision, parameter :: noisepe_TCR        =
     &            1.d0 / (2.5d0 * 1000.d0)


c Synaptic conductance time constants. 
      real*8, parameter :: tauAMPA_suppyrRS_to_suppyrRS=2.d0 
      real*8, parameter :: tauNMDA_suppyrRS_to_suppyrRS=130.5d0 
      real*8, parameter :: tauAMPA_suppyrRS_to_suppyrFRB=2.d0 
      real*8, parameter :: tauNMDA_suppyrRS_to_suppyrFRB=130.d0  
      real*8, parameter :: tauAMPA_suppyrRS_to_supbask  =.8d0   
      real*8, parameter :: tauNMDA_suppyrRS_to_supbask  =100.d0 
      real*8, parameter :: tauAMPA_suppyrRS_to_supng    =.8d0   
      real*8, parameter :: tauNMDA_suppyrRS_to_supng    =100.d0 
      real*8, parameter :: tauAMPA_suppyrRS_to_supaxax  =.8d0  
      real*8, parameter :: tauNMDA_suppyrRS_to_supaxax  =100.d0 
      real*8, parameter :: tauAMPA_suppyrRS_to_supLTS   =1.d0  
      real*8, parameter :: tauNMDA_suppyrRS_to_supLTS   =100.d0 
      real*8, parameter :: tauAMPA_suppyrRS_to_spinstell=2.d0   
      real*8, parameter :: tauNMDA_suppyrRS_to_spinstell=130.d0 
      real*8, parameter :: tauAMPA_suppyrRS_to_tuftIB   =2.d0   
      real*8, parameter :: tauNMDA_suppyrRS_to_tuftIB   =130.d0 
      real*8, parameter :: tauAMPA_suppyrRS_to_tuftRS   =2.d0   
      real*8, parameter :: tauNMDA_suppyrRS_to_tuftRS   =130.d0 
      real*8, parameter :: tauAMPA_suppyrRS_to_deepbask =.8d0   
      real*8, parameter :: tauNMDA_suppyrRS_to_deepbask =100.d0 
      real*8, parameter :: tauAMPA_suppyrRS_to_deepaxax =.8d0   
      real*8, parameter :: tauNMDA_suppyrRS_to_deepaxax =100.d0 
      real*8, parameter :: tauAMPA_suppyrRS_to_deepLTS  =1.d0   
      real*8, parameter :: tauNMDA_suppyrRS_to_deepLTS  =100.d0 
      real*8, parameter :: tauAMPA_suppyrRS_to_nontuftRS=2.d0   
      real*8, parameter :: tauNMDA_suppyrRS_to_nontuftRS=130.d0 

      real*8, parameter :: tauAMPA_suppyrFRB_to_suppyrRS=2.d0   
      real*8, parameter :: tauNMDA_suppyrFRB_to_suppyrRS=130.d0  
      real*8, parameter :: tauAMPA_suppyrFRB_to_suppyrFRB=2.d0   
      real*8, parameter :: tauNMDA_suppyrFRB_to_suppyrFRB=130.d0 
      real*8, parameter :: tauAMPA_suppyrFRB_to_supbask  =.8d0   
      real*8, parameter :: tauNMDA_suppyrFRB_to_supbask  =100.d0 
      real*8, parameter :: tauAMPA_suppyrFRB_to_supng    =.8d0   
      real*8, parameter :: tauNMDA_suppyrFRB_to_supng    =100.d0 
      real*8, parameter :: tauAMPA_suppyrFRB_to_supaxax  =.8d0  
      real*8, parameter :: tauNMDA_suppyrFRB_to_supaxax  =100.d0 
      real*8, parameter :: tauAMPA_suppyrFRB_to_supLTS   =1.d0  
      real*8, parameter :: tauNMDA_suppyrFRB_to_supLTS   =100.d0 
      real*8, parameter :: tauAMPA_suppyrFRB_to_spinstell=2.d0   
      real*8, parameter :: tauNMDA_suppyrFRB_to_spinstell=130.d0 
      real*8, parameter :: tauAMPA_suppyrFRB_to_tuftIB   =2.d0   
      real*8, parameter :: tauNMDA_suppyrFRB_to_tuftIB   =130.d0 
      real*8, parameter :: tauAMPA_suppyrFRB_to_tuftRS   =2.d0   
      real*8, parameter :: tauNMDA_suppyrFRB_to_tuftRS   =130.d0
      real*8, parameter :: tauAMPA_suppyrFRB_to_deepbask =.8d0   
      real*8, parameter :: tauNMDA_suppyrFRB_to_deepbask =100.d0 
      real*8, parameter :: tauAMPA_suppyrFRB_to_deepaxax =.8d0   
      real*8, parameter :: tauNMDA_suppyrFRB_to_deepaxax =100.d0 
      real*8, parameter :: tauAMPA_suppyrFRB_to_deepLTS  =1.d0   
      real*8, parameter :: tauNMDA_suppyrFRB_to_deepLTS  =100.d0 
      real*8, parameter :: tauAMPA_suppyrFRB_to_nontuftRS=2.d0   
      real*8, parameter :: tauNMDA_suppyrFRB_to_nontuftRS=130.d0 

      real*8,  parameter :: tauGABA_supbask_to_suppyrRS   =6.d0 ! 29 Nov. 2005, reduce from 6 to 5, also below. 
      real*8,  parameter :: tauGABA_supbask_to_suppyrFRB  =6.d0
      real*8,  parameter :: tauGABA_supbask_to_supbask    =3.d0  
      real*8,  parameter :: tauGABA_supbask_to_supng      =3.d0  
      real*8,  parameter :: tauGABA_supbask_to_supaxax    =3.d0  
      real*8,  parameter :: tauGABA_supbask_to_supLTS     =3.d0  
      real*8,  parameter :: tauGABA_supbask_to_spinstell  =6.d0 

      real*8,  parameter :: tauGABA_supaxax_to_suppyrRS   =6.d0 
      real*8,  parameter :: tauGABA_supaxax_to_suppyrFRB  =6.d0 
      real*8,  parameter :: tauGABA_supaxax_to_spinstell  =6.d0 
      real*8,  parameter :: tauGABA_supaxax_to_tuftIB     =6.d0 
      real*8,  parameter :: tauGABA_supaxax_to_tuftRS     =6.d0 
      real*8,  parameter :: tauGABA_supaxax_to_nontuftRS  =6.d0 

      real*8, parameter :: tauGABA_supLTS_to_suppyrRS    =20.d0 
      real*8, parameter :: tauGABA_supLTS_to_suppyrFRB   =20.d0 
      real*8, parameter :: tauGABA_supLTS_to_supbask     =20.d0 
      real*8, parameter :: tauGABA_supLTS_to_supaxax     =20.d0 
      real*8, parameter :: tauGABA_supLTS_to_supLTS      =20.d0 
      real*8, parameter :: tauGABA_supLTS_to_spinstell   =20.d0 
      real*8, parameter :: tauGABA_supLTS_to_tuftIB      =20.d0 
      real*8, parameter :: tauGABA_supLTS_to_tuftRS      =20.d0 
      real*8, parameter :: tauGABA_supLTS_to_deepbask    =20.d0 
      real*8, parameter :: tauGABA_supLTS_to_deepaxax    =20.d0 
      real*8, parameter :: tauGABA_supLTS_to_deepLTS     =20.d0 
      real*8, parameter :: tauGABA_supLTS_to_nontuftRS   =20.d0  

      real*8, parameter:: tauGABA_supng_to_suppyrRS      =6.d0
      real*8, parameter:: tauGABA_supng_to_suppyrFRB     =6.d0
      real*8, parameter:: tauGABA_supng_to_nontuftRS     =6.d0
      real*8, parameter:: tauGABA_supng_to_tuftIB        =6.d0
      real*8, parameter:: tauGABA_supng_to_tuftRS        =6.d0
      real*8, parameter:: tauGABA_supng_to_supng         =3.d0
      real*8, parameter:: tauGABA_supng_to_supbask       =3.d0

      real*8, parameter :: tauAMPA_spinstell_to_suppyrRS =2.d0  
      real*8, parameter :: tauNMDA_spinstell_to_suppyrRS =130.d0 
      real*8, parameter :: tauAMPA_spinstell_to_suppyrFRB=2.d0  
      real*8, parameter :: tauNMDA_spinstell_to_suppyrFRB=130.d0 
      real*8, parameter :: tauAMPA_spinstell_to_supbask  =.8d0  
      real*8, parameter :: tauNMDA_spinstell_to_supbask  =100.d0
      real*8, parameter :: tauAMPA_spinstell_to_supaxax  =.8d0  
      real*8, parameter :: tauNMDA_spinstell_to_supaxax  =100.d0
      real*8, parameter :: tauAMPA_spinstell_to_supLTS   =1.d0  
      real*8, parameter :: tauNMDA_spinstell_to_supLTS   =100.d0
      real*8, parameter :: tauAMPA_spinstell_to_spinstell=2.d0  
!     real*8, parameter :: tauNMDA_spinstell_to_spinstell=130.d0 
      real*8, parameter :: tauNMDA_spinstell_to_spinstell= 15.d0 ! small tau per Fleidervish et al., NEURON 
      real*8, parameter :: tauAMPA_spinstell_to_tuftIB   =2.d0  
      real*8, parameter :: tauNMDA_spinstell_to_tuftIB   =130.d0 
      real*8, parameter :: tauAMPA_spinstell_to_tuftRS   =2.d0  
      real*8, parameter :: tauNMDA_spinstell_to_tuftRS   =130.d0
      real*8, parameter :: tauAMPA_spinstell_to_deepbask =.8d0  
      real*8, parameter :: tauNMDA_spinstell_to_deepbask =100.d0
      real*8, parameter :: tauAMPA_spinstell_to_deepng   =.8d0  
      real*8, parameter :: tauNMDA_spinstell_to_deepng   =100.d0
      real*8, parameter :: tauAMPA_spinstell_to_deepaxax =.8d0  
      real*8, parameter :: tauNMDA_spinstell_to_deepaxax =100.d0
      real*8, parameter :: tauAMPA_spinstell_to_deepLTS  =1.d0  
      real*8, parameter :: tauNMDA_spinstell_to_deepLTS  =100.d0
      real*8, parameter :: tauAMPA_spinstell_to_nontuftRS=2.d0  
      real*8, parameter :: tauNMDA_spinstell_to_nontuftRS=130.d0

      real*8, parameter :: tauAMPA_tuftIB_to_suppyrRS    =2.d0 
      real*8, parameter :: tauNMDA_tuftIB_to_suppyrRS    =130.d0
      real*8, parameter :: tauAMPA_tuftIB_to_suppyrFRB   =2.d0 
      real*8, parameter :: tauNMDA_tuftIB_to_suppyrFRB   =130.d0
      real*8, parameter :: tauAMPA_tuftIB_to_supbask     =.8d0  
      real*8, parameter :: tauNMDA_tuftIB_to_supbask     =100.d0 
      real*8, parameter :: tauAMPA_tuftIB_to_supaxax     =.8d0  
      real*8, parameter :: tauNMDA_tuftIB_to_supaxax     =100.d0 
      real*8, parameter :: tauAMPA_tuftIB_to_supLTS      =1.d0  
      real*8, parameter :: tauNMDA_tuftIB_to_supLTS      =100.d0 
      real*8, parameter :: tauAMPA_tuftIB_to_spinstell   =2.d0   
      real*8, parameter :: tauNMDA_tuftIB_to_spinstell   =130.d0 
      real*8, parameter :: tauAMPA_tuftIB_to_tuftIB      =2.d0  
      real*8, parameter :: tauNMDA_tuftIB_to_tuftIB      =130.d0 
      real*8, parameter :: tauAMPA_tuftIB_to_tuftRS      =2.0d0 
      real*8, parameter :: tauNMDA_tuftIB_to_tuftRS      =130.d0 
      real*8, parameter :: tauAMPA_tuftIB_to_deepbask    =.8d0  
      real*8, parameter :: tauNMDA_tuftIB_to_deepbask    =100.d0 
      real*8, parameter :: tauAMPA_tuftIB_to_deepng      =.8d0  
      real*8, parameter :: tauNMDA_tuftIB_to_deepng      =100.d0 
      real*8, parameter :: tauAMPA_tuftIB_to_deepaxax    =.8d0  
      real*8, parameter :: tauNMDA_tuftIB_to_deepaxax    =100.d0 
      real*8, parameter :: tauAMPA_tuftIB_to_deepLTS     =1.d0  
      real*8, parameter :: tauNMDA_tuftIB_to_deepLTS     =100.d0 
      real*8, parameter :: tauAMPA_tuftIB_to_nontuftRS   =2.0d0 
      real*8, parameter :: tauNMDA_tuftIB_to_nontuftRS   =130.d0 

      real*8, parameter :: tauAMPA_tuftRS_to_suppyrRS    =2.d0 
      real*8, parameter :: tauNMDA_tuftRS_to_suppyrRS    =130.d0
      real*8, parameter :: tauAMPA_tuftRS_to_suppyrFRB   =2.d0 
      real*8, parameter :: tauNMDA_tuftRS_to_suppyrFRB   =130.d0
      real*8, parameter :: tauAMPA_tuftRS_to_supbask     =.8d0  
      real*8, parameter :: tauNMDA_tuftRS_to_supbask     =100.d0 
      real*8, parameter :: tauAMPA_tuftRS_to_supaxax     =.8d0  
      real*8, parameter :: tauNMDA_tuftRS_to_supaxax     =100.d0 
      real*8, parameter :: tauAMPA_tuftRS_to_supLTS      =1.d0  
      real*8, parameter :: tauNMDA_tuftRS_to_supLTS      =100.d0 
      real*8, parameter :: tauAMPA_tuftRS_to_spinstell   =2.d0  
      real*8, parameter :: tauNMDA_tuftRS_to_spinstell   =130.d0 
      real*8, parameter :: tauAMPA_tuftRS_to_tuftIB      =2.d0  
      real*8, parameter :: tauNMDA_tuftRS_to_tuftIB      =130.d0 
      real*8, parameter :: tauAMPA_tuftRS_to_tuftRS      =2.d0  
      real*8, parameter :: tauNMDA_tuftRS_to_tuftRS      =130.d0 
      real*8, parameter :: tauAMPA_tuftRS_to_deepbask    =.8d0  
      real*8, parameter :: tauNMDA_tuftRS_to_deepbask    =100.d0 
      real*8, parameter :: tauAMPA_tuftRS_to_deepng      =.8d0  
      real*8, parameter :: tauNMDA_tuftRS_to_deepng      =100.d0 
      real*8, parameter :: tauAMPA_tuftRS_to_deepaxax    =.8d0  
      real*8, parameter :: tauNMDA_tuftRS_to_deepaxax    =100.d0 
      real*8, parameter :: tauAMPA_tuftRS_to_deepLTS     =1.d0   
      real*8, parameter :: tauNMDA_tuftRS_to_deepLTS     =100.d0 
      real*8, parameter :: tauAMPA_tuftRS_to_nontuftRS   =2.d0  
      real*8, parameter :: tauNMDA_tuftRS_to_nontuftRS   =130.d0 

      real*8, parameter :: tauGABA_deepbask_to_spinstell =6.d0 
      real*8, parameter :: tauGABA_deepbask_to_tuftIB    =6.d0  
      real*8, parameter :: tauGABA_deepbask_to_tuftRS    =6.d0  
      real*8, parameter :: tauGABA_deepbask_to_deepbask  =3.d0  
      real*8, parameter :: tauGABA_deepbask_to_deepaxax  =3.d0  
      real*8, parameter :: tauGABA_deepbask_to_deepLTS   =3.d0  
      real*8, parameter :: tauGABA_deepbask_to_deepng    =3.d0  
      real*8, parameter :: tauGABA_deepbask_to_nontuftRS =6.d0  

      real*8, parameter :: tauGABA_deepaxax_to_suppyrRS   =6.d0 
      real*8, parameter :: tauGABA_deepaxax_to_suppyrFRB  =6.d0 
      real*8, parameter :: tauGABA_deepaxax_to_spinstell  =6.d0 
      real*8, parameter :: tauGABA_deepaxax_to_tuftIB     =6.d0 
      real*8, parameter :: tauGABA_deepaxax_to_tuftRS     =6.d0 
      real*8, parameter :: tauGABA_deepaxax_to_nontuftRS  =6.d0 

      real*8, parameter :: tauGABA_deepLTS_to_suppyrRS    =20.d0 
      real*8, parameter :: tauGABA_deepLTS_to_suppyrFRB   =20.d0 
      real*8, parameter :: tauGABA_deepLTS_to_supbask     =20.d0 
      real*8, parameter :: tauGABA_deepLTS_to_supaxax     =20.d0 
      real*8, parameter :: tauGABA_deepLTS_to_supLTS      =20.d0 
      real*8, parameter :: tauGABA_deepLTS_to_spinstell   =20.d0 
      real*8, parameter :: tauGABA_deepLTS_to_tuftIB      =20.d0 
      real*8, parameter :: tauGABA_deepLTS_to_tuftRS      =20.d0 
      real*8, parameter :: tauGABA_deepLTS_to_deepbask    =20.d0 
      real*8, parameter :: tauGABA_deepLTS_to_deepaxax    =20.d0 
      real*8, parameter :: tauGABA_deepLTS_to_deepLTS     =20.d0 
      real*8, parameter :: tauGABA_deepLTS_to_nontuftRS   =20.d0 

      real*8, parameter :: tauGABA_deepng_to_tuftIB       =6.d0
      real*8, parameter :: tauGABA_deepng_to_tuftRS       =6.d0
      real*8, parameter :: tauGABA_deepng_to_nontuftRS    =6.d0
      real*8, parameter :: tauGABA_deepng_to_spinstell    =6.d0
      real*8, parameter :: tauGABA_deepng_to_deepng       =3.d0
      real*8, parameter :: tauGABA_deepng_to_deepbask     =3.d0

      real*8, parameter :: tauAMPA_TCR_to_suppyrRS        =2.d0  
      real*8, parameter :: tauNMDA_TCR_to_suppyrRS        =130.d0
      real*8, parameter :: tauAMPA_TCR_to_suppyrFRB       =2.d0  
      real*8, parameter :: tauNMDA_TCR_to_suppyrFRB       =130.d0
c     real*8, parameter :: tauAMPA_TCR_to_supbask         =1.d0  
      real*8, parameter :: tauAMPA_TCR_to_supbask         =0.75d0  
      real*8, parameter :: tauNMDA_TCR_to_supbask         =100.d0
      real*8, parameter :: tauAMPA_TCR_to_supng           =0.75d0  
      real*8, parameter :: tauNMDA_TCR_to_supng           =100.d0
      real*8, parameter :: tauAMPA_TCR_to_supaxax         =1.d0  
      real*8, parameter :: tauNMDA_TCR_to_supaxax         =100.d0 
      real*8, parameter :: tauAMPA_TCR_to_spinstell       =2.0d0 
      real*8, parameter :: tauNMDA_TCR_to_spinstell       =130.d0
      real*8, parameter :: tauAMPA_TCR_to_tuftIB          =2.d0  
      real*8, parameter :: tauNMDA_TCR_to_tuftIB          =130.d0
      real*8, parameter :: tauAMPA_TCR_to_tuftRS          =2.d0  
      real*8, parameter :: tauNMDA_TCR_to_tuftRS          =130.d0
!     real*8, parameter :: tauAMPA_TCR_to_deepbask        =1.d0  
      real*8, parameter :: tauAMPA_TCR_to_deepbask        =0.75d0  
      real*8, parameter :: tauNMDA_TCR_to_deepbask        =100.d0
      real*8, parameter :: tauAMPA_TCR_to_deepng          =0.75d0  
      real*8, parameter :: tauNMDA_TCR_to_deepng          =100.d0
!     real*8, parameter :: tauAMPA_TCR_to_deepaxax        =1.d0  
      real*8, parameter :: tauAMPA_TCR_to_deepaxax        =0.75d0  
      real*8, parameter :: tauNMDA_TCR_to_deepaxax        =100.d0
      real*8, parameter :: tauAMPA_TCR_to_nRT             =2.0d0      
      real*8, parameter :: tauNMDA_TCR_to_nRT             =150.d0
      real*8, parameter :: tauAMPA_TCR_to_nontuftRS       =2.0d0     
      real*8, parameter :: tauNMDA_TCR_to_nontuftRS       =130.d0

!     real*8, parameter :: tauGABA1_nRT_to_TCR             =10.d0 
!     real*8, parameter :: tauGABA2_nRT_to_TCR             =30.d0 
!     real*8, parameter :: tauGABA1_nRT_to_nRT             =18.d0 
!     real*8, parameter :: tauGABA2_nRT_to_nRT             =89.d0 
! See notebook entry of 17 Feb. 2004.
! Speed these up per Huntsman & Huguenard (2000)
      real*8, parameter :: tauGABA1_nRT_to_TCR             =3.30d0 
      real*8, parameter :: tauGABA2_nRT_to_TCR             =10.d0 
      real*8, parameter :: tauGABA1_nRT_to_nRT             = 9.d0 
      real*8, parameter :: tauGABA2_nRT_to_nRT             =44.5d0 

      real*8, parameter :: tauAMPA_nontuftRS_to_suppyrRS  =2.d0  
      real*8, parameter :: tauNMDA_nontuftRS_to_suppyrRS  =130.d0
      real*8, parameter :: tauAMPA_nontuftRS_to_suppyrFRB =2.d0  
      real*8, parameter :: tauNMDA_nontuftRS_to_suppyrFRB =130.d0
      real*8, parameter :: tauAMPA_nontuftRS_to_supbask   =.8d0  
      real*8, parameter :: tauNMDA_nontuftRS_to_supbask   =100.d0
      real*8, parameter :: tauAMPA_nontuftRS_to_supaxax   =.8d0  
      real*8, parameter :: tauNMDA_nontuftRS_to_supaxax   =100.d0 
      real*8, parameter :: tauAMPA_nontuftRS_to_supLTS    =1.0d0 
      real*8, parameter :: tauNMDA_nontuftRS_to_supLTS    =100.d0
      real*8, parameter :: tauAMPA_nontuftRS_to_spinstell =2.d0  
      real*8, parameter :: tauNMDA_nontuftRS_to_spinstell =130.d0
      real*8, parameter :: tauAMPA_nontuftRS_to_tuftIB    =2.d0  
      real*8, parameter :: tauNMDA_nontuftRS_to_tuftIB    =130.d0
      real*8, parameter :: tauAMPA_nontuftRS_to_tuftRS    =2.d0  
      real*8, parameter :: tauNMDA_nontuftRS_to_tuftRS    =130.d0
      real*8, parameter :: tauAMPA_nontuftRS_to_deepbask  =.8d0  
      real*8, parameter :: tauNMDA_nontuftRS_to_deepbask  =100.d0
      real*8, parameter :: tauAMPA_nontuftRS_to_deepng    =.8d0  
      real*8, parameter :: tauNMDA_nontuftRS_to_deepng    =100.d0
      real*8, parameter :: tauAMPA_nontuftRS_to_deepaxax  =.8d0   
      real*8, parameter :: tauNMDA_nontuftRS_to_deepaxax  =100.d0
      real*8, parameter :: tauAMPA_nontuftRS_to_deepLTS   =1.d0  
      real*8, parameter :: tauNMDA_nontuftRS_to_deepLTS   =100.d0
      real*8, parameter :: tauAMPA_nontuftRS_to_TCR       =2.d0  
      real*8, parameter :: tauNMDA_nontuftRS_to_TCR       =130.d0 
      real*8, parameter :: tauAMPA_nontuftRS_to_nRT       =2.0d0 
      real*8, parameter :: tauNMDA_nontuftRS_to_nRT       =100.d0 
      real*8, parameter :: tauAMPA_nontuftRS_to_nontuftRS =2.d0  
      real*8, parameter :: tauNMDA_nontuftRS_to_nontuftRS =130.d0 
c End definition of synaptic time constants

c Synaptic conductance scaling factors.
      real*8 gAMPA_suppyrRS_to_suppyrRS/1.00d-3/
      real*8 gNMDA_suppyrRS_to_suppyrRS/0.100d-3/
      real*8 gAMPA_suppyrRS_to_suppyrFRB/0.25d-3/
      real*8 gNMDA_suppyrRS_to_suppyrFRB/0.025d-3/
      real*8 gAMPA_suppyrRS_to_supbask  /3.00d-3/
c     real*8 gNMDA_suppyrRS_to_supbask  /0.15d-3/
      real*8 gNMDA_suppyrRS_to_supbask  /0.00d-3/
c     real*8 gAMPA_suppyrRS_to_supng    /2.00d-3/
      real*8 gAMPA_suppyrRS_to_supng    /0.80d-3/
c     real*8 gNMDA_suppyrRS_to_supng    /0.10d-3/
      real*8 gNMDA_suppyrRS_to_supng    /0.00d-3/
      real*8 gAMPA_suppyrRS_to_supaxax  /3.0d-3/
c     real*8 gNMDA_suppyrRS_to_supaxax  /0.15d-3/
      real*8 gNMDA_suppyrRS_to_supaxax  /0.00d-3/
      real*8 gAMPA_suppyrRS_to_supLTS   /2.0d-3/
c     real*8 gNMDA_suppyrRS_to_supLTS   /0.15d-3/
      real*8 gNMDA_suppyrRS_to_supLTS   /0.00d-3/
      real*8 gAMPA_suppyrRS_to_spinstell/0.10d-3/
      real*8 gNMDA_suppyrRS_to_spinstell/0.01d-3/
      real*8 gAMPA_suppyrRS_to_tuftIB   /0.10d-3/
      real*8 gNMDA_suppyrRS_to_tuftIB   /0.01d-3/
      real*8 gAMPA_suppyrRS_to_tuftRS   /0.10d-3/
      real*8 gNMDA_suppyrRS_to_tuftRS   /0.01d-3/
      real*8 gAMPA_suppyrRS_to_deepbask /1.00d-3/
      real*8 gNMDA_suppyrRS_to_deepbask /0.10d-3/
      real*8 gAMPA_suppyrRS_to_deepaxax /1.00d-3/
      real*8 gNMDA_suppyrRS_to_deepaxax /0.10d-3/
      real*8 gAMPA_suppyrRS_to_deepLTS  /1.00d-3/
      real*8 gNMDA_suppyrRS_to_deepLTS  /0.05d-3/
      real*8 gAMPA_suppyrRS_to_nontuftRS/0.10d-3/
      real*8 gNMDA_suppyrRS_to_nontuftRS/0.05d-3/

      real*8 gAMPA_suppyrFRB_to_suppyrRS/0.25d-3/
      real*8 gNMDA_suppyrFRB_to_suppyrRS/0.025d-3/
      real*8 gAMPA_suppyrFRB_to_suppyrFRB/0.25d-3/
      real*8 gNMDA_suppyrFRB_to_suppyrFRB/.025d-3/
      real*8 gAMPA_suppyrFRB_to_supbask  /3.00d-3/
c     real*8 gNMDA_suppyrFRB_to_supbask  /0.10d-3/
      real*8 gNMDA_suppyrFRB_to_supbask  /0.00d-3/
c     real*8 gAMPA_suppyrFRB_to_supng    /2.00d-3/
      real*8 gAMPA_suppyrFRB_to_supng    /0.20d-3/
c     real*8 gNMDA_suppyrFRB_to_supng    /0.10d-3/
      real*8 gNMDA_suppyrFRB_to_supng    /0.00d-3/
      real*8 gAMPA_suppyrFRB_to_supaxax  /3.0d-3/
c     real*8 gNMDA_suppyrFRB_to_supaxax  /0.10d-3/
      real*8 gNMDA_suppyrFRB_to_supaxax  /0.00d-3/
      real*8 gAMPA_suppyrFRB_to_supLTS   /2.0d-3/
c     real*8 gNMDA_suppyrFRB_to_supLTS   /0.10d-3/
      real*8 gNMDA_suppyrFRB_to_supLTS   /0.00d-3/
      real*8 gAMPA_suppyrFRB_to_spinstell/0.10d-3/
      real*8 gNMDA_suppyrFRB_to_spinstell/0.01d-3/
      real*8 gAMPA_suppyrFRB_to_tuftIB   /0.10d-3/
      real*8 gNMDA_suppyrFRB_to_tuftIB   /0.01d-3/
      real*8 gAMPA_suppyrFRB_to_tuftRS   /0.10d-3/
      real*8 gNMDA_suppyrFRB_to_tuftRS   /0.01d-3/
      real*8 gAMPA_suppyrFRB_to_deepbask /1.00d-3/
      real*8 gNMDA_suppyrFRB_to_deepbask /0.10d-3/
      real*8 gAMPA_suppyrFRB_to_deepaxax /1.00d-3/
      real*8 gNMDA_suppyrFRB_to_deepaxax /0.10d-3/
      real*8 gAMPA_suppyrFRB_to_deepLTS  /1.00d-3/
      real*8 gNMDA_suppyrFRB_to_deepLTS  /0.05d-3/
      real*8 gAMPA_suppyrFRB_to_nontuftRS/0.05d-3/
      real*8 gNMDA_suppyrFRB_to_nontuftRS/0.05d-3/

c     real*8 gGABA_supbask_to_suppyrRS   /1.2d-3/
      real*8 gGABA_supbask_to_suppyrRS   /0.4d-3/
c     real*8 gGABA_supbask_to_suppyrRS   /0.0d-3/ ! try to make gamma robust
c     real*8 gGABA_supbask_to_suppyrFRB  /1.2d-3/
      real*8 gGABA_supbask_to_suppyrFRB  /0.0d-3/ ! try to make gamma robust
      real*8 gGABA_supbask_to_supbask    /0.2d-3/
      real*8 gGABA_supbask_to_supng      /0.2d-3/
      real*8 gGABA_supbask_to_supaxax    /0.2d-3/
      real*8 gGABA_supbask_to_supLTS     /0.5d-3/
!     real*8 gGABA_supbask_to_spinstell  /0.7d-3/
      real*8 gGABA_supbask_to_spinstell  /0.1d-3/ ! if main inhib. to spinstell from deep int.

c     real*8 gGABA_supng_to_suppyrRS     /0.8d-3/
      real*8 gGABA_supng_to_suppyrRS     /0.1d-3/
      real*8 gGABA_supng_to_suppyrFRB    /0.0d-3/
      real*8 gGABA_supng_to_nontuftRS    /0.8d-3/
c     real*8 gGABA_supng_to_nontuftRS    /0.0d-3/
      real*8 gGABA_supng_to_tuftIB       /0.8d-3/
c     real*8 gGABA_supng_to_tuftIB       /0.0d-3/
      real*8 gGABA_supng_to_tuftRS       /0.0d-3/
      real*8 gGABA_supng_to_supng        /0.2d-3/
      real*8 gGABA_supng_to_supbask      /0.2d-3/

      real*8 gGABAB_supng_to_suppyrRS    /0.005d-3/
c     real*8 gGABAB_supng_to_suppyrRS    /0.070d-3/
c     real*8 gGABAB_supng_to_suppyrRS    /0.000d-3/
c     real*8 gGABAB_supng_to_suppyrFRB   /0.025d-3/
      real*8 gGABAB_supng_to_suppyrFRB   /0.070d-3/
c     real*8 gGABAB_supng_to_suppyrFRB   /0.005d-3/
      real*8 gGABAB_supng_to_nontuftRS   /0.0003d-3/
c     real*8 gGABAB_supng_to_nontuftRS   /0.0000d-3/
      real*8 gGABAB_supng_to_tuftIB      /0.035d-3/
c     real*8 gGABAB_supng_to_tuftIB      /0.000d-3/
      real*8 gGABAB_supng_to_tuftRS      /0.025d-3/

      real*8 gGABA_supaxax_to_suppyrRS   /0.2d-3/
      real*8 gGABA_supaxax_to_suppyrFRB  /0.0d-3/
!     real*8 gGABA_supaxax_to_spinstell  /1.0d-3/
      real*8 gGABA_supaxax_to_spinstell  /0.1d-3/ ! if main inhib. to spinstell from deep int.
      real*8 gGABA_supaxax_to_tuftIB     /1.0d-3/
      real*8 gGABA_supaxax_to_tuftRS     /1.0d-3/
      real*8 gGABA_supaxax_to_nontuftRS  /0.5d-3/


      real*8 gGABA_supLTS_to_suppyrRS    /.00d-3/
      real*8 gGABA_supLTS_to_suppyrFRB   /.00d-3/
      real*8 gGABA_supLTS_to_supbask     /.01d-3/
      real*8 gGABA_supLTS_to_supaxax     /.01d-3/
      real*8 gGABA_supLTS_to_supLTS      /.05d-3/
      real*8 gGABA_supLTS_to_spinstell   /.01d-3/
      real*8 gGABA_supLTS_to_tuftIB      /.02d-3/
      real*8 gGABA_supLTS_to_tuftRS      /.02d-3/
      real*8 gGABA_supLTS_to_deepbask    /.01d-3/
      real*8 gGABA_supLTS_to_deepaxax    /.00d-3/
      real*8 gGABA_supLTS_to_deepLTS     /.05d-3/
      real*8 gGABA_supLTS_to_nontuftRS   /.02d-3/

      real*8 gAMPA_spinstell_to_suppyrRS /0.2d-3/
      real*8 gNMDA_spinstell_to_suppyrRS /0.1d-3/
      real*8 gAMPA_spinstell_to_suppyrFRB/1.0d-3/
      real*8 gNMDA_spinstell_to_suppyrFRB/0.1d-3/
      real*8 gAMPA_spinstell_to_supbask  /1.0d-3/
c     real*8 gNMDA_spinstell_to_supbask  /.15d-3/
      real*8 gNMDA_spinstell_to_supbask  /.00d-3/
      real*8 gAMPA_spinstell_to_supaxax  /1.0d-3/
c     real*8 gNMDA_spinstell_to_supaxax  /.15d-3/
      real*8 gNMDA_spinstell_to_supaxax  /.00d-3/
      real*8 gAMPA_spinstell_to_supLTS   /1.0d-3/
c     real*8 gNMDA_spinstell_to_supLTS   /.15d-3/
      real*8 gNMDA_spinstell_to_supLTS   /.00d-3/
      real*8 gAMPA_spinstell_to_spinstell/1.0d-3/
      real*8 gNMDA_spinstell_to_spinstell/0.1d-3/
      real*8 gAMPA_spinstell_to_tuftIB   /1.0d-3/
      real*8 gNMDA_spinstell_to_tuftIB   /0.1d-3/
      real*8 gAMPA_spinstell_to_tuftRS   /1.0d-3/
      real*8 gNMDA_spinstell_to_tuftRS   /0.1d-3/
      real*8 gAMPA_spinstell_to_deepbask /1.0d-3/
      real*8 gNMDA_spinstell_to_deepbask /.15d-3/
c     real*8 gAMPA_spinstell_to_deepng   /1.0d-3/
      real*8 gAMPA_spinstell_to_deepng   /0.4d-3/
      real*8 gNMDA_spinstell_to_deepng   /.15d-3/
      real*8 gAMPA_spinstell_to_deepaxax /1.0d-3/
      real*8 gNMDA_spinstell_to_deepaxax /.15d-3/
      real*8 gAMPA_spinstell_to_deepLTS  /0.5d-3/
      real*8 gNMDA_spinstell_to_deepLTS  /.05d-3/
      real*8 gAMPA_spinstell_to_nontuftRS/0.1d-3/
      real*8 gNMDA_spinstell_to_nontuftRS/0.1d-3/

c     real*8 gAMPA_tuftIB_to_suppyrRS    /3.0d-3/
      real*8 gAMPA_tuftIB_to_suppyrRS    /0.0d-3/
      real*8 gNMDA_tuftIB_to_suppyrRS    /0.15d-3/
      real*8 gAMPA_tuftIB_to_suppyrFRB   /0.5d-3/
      real*8 gNMDA_tuftIB_to_suppyrFRB   /0.05d-3/
      real*8 gAMPA_tuftIB_to_supbask     /1.0d-3/
c     real*8 gNMDA_tuftIB_to_supbask     /0.15d-3/
      real*8 gNMDA_tuftIB_to_supbask     /0.00d-3/
      real*8 gAMPA_tuftIB_to_supaxax     /1.0d-3/
c     real*8 gNMDA_tuftIB_to_supaxax     /0.15d-3/
      real*8 gNMDA_tuftIB_to_supaxax     /0.00d-3/
      real*8 gAMPA_tuftIB_to_supLTS      /1.0d-3/
c     real*8 gNMDA_tuftIB_to_supLTS      /0.15d-3/
      real*8 gNMDA_tuftIB_to_supLTS      /0.00d-3/
      real*8 gAMPA_tuftIB_to_spinstell   /0.5d-3/
      real*8 gNMDA_tuftIB_to_spinstell   /0.05d-3/
c     real*8 gAMPA_tuftIB_to_tuftIB      /2.0d-3/
      real*8 gAMPA_tuftIB_to_tuftIB      /3.0d-3/
c     real*8 gNMDA_tuftIB_to_tuftIB      /0.20d-3/
      real*8 gNMDA_tuftIB_to_tuftIB      /0.07d-3/
      real*8 gAMPA_tuftIB_to_tuftRS      /2.0d-3/
      real*8 gNMDA_tuftIB_to_tuftRS      /0.20d-3/
      real*8 gAMPA_tuftIB_to_deepbask    /3.0d-3/
      real*8 gNMDA_tuftIB_to_deepbask    /0.15d-3/
c     real*8 gAMPA_tuftIB_to_deepng      /2.0d-3/
      real*8 gAMPA_tuftIB_to_deepng      /1.2d-3/
c     real*8 gAMPA_tuftIB_to_deepng      /3.0d-3/
      real*8 gNMDA_tuftIB_to_deepng      /0.10d-3/
c     real*8 gNMDA_tuftIB_to_deepng      /0.50d-3/
      real*8 gAMPA_tuftIB_to_deepaxax    /3.0d-3/
      real*8 gNMDA_tuftIB_to_deepaxax    /0.15d-3/
      real*8 gAMPA_tuftIB_to_deepLTS     /1.0d-3/
      real*8 gNMDA_tuftIB_to_deepLTS     /0.05d-3/
      real*8 gAMPA_tuftIB_to_nontuftRS   /3.00d-3/
      real*8 gNMDA_tuftIB_to_nontuftRS   /0.01d-3/

      real*8 gAMPA_tuftRS_to_suppyrRS    /0.5d-3/
      real*8 gNMDA_tuftRS_to_suppyrRS    /0.05d-3/
      real*8 gAMPA_tuftRS_to_suppyrFRB   /0.5d-3/
      real*8 gNMDA_tuftRS_to_suppyrFRB   /0.05d-3/
      real*8 gAMPA_tuftRS_to_supbask     /1.0d-3/
c     real*8 gNMDA_tuftRS_to_supbask     /0.15d-3/
      real*8 gNMDA_tuftRS_to_supbask     /0.00d-3/
      real*8 gAMPA_tuftRS_to_supaxax     /1.0d-3/
c     real*8 gNMDA_tuftRS_to_supaxax     /0.15d-3/
      real*8 gNMDA_tuftRS_to_supaxax     /0.00d-3/
      real*8 gAMPA_tuftRS_to_supLTS      /1.0d-3/
c     real*8 gNMDA_tuftRS_to_supLTS      /0.15d-3/
      real*8 gNMDA_tuftRS_to_supLTS      /0.00d-3/
      real*8 gAMPA_tuftRS_to_spinstell   /0.5d-3/
      real*8 gNMDA_tuftRS_to_spinstell   /0.05d-3/
      real*8 gAMPA_tuftRS_to_tuftIB      /1.0d-3/
      real*8 gNMDA_tuftRS_to_tuftIB      /0.10d-3/
      real*8 gAMPA_tuftRS_to_tuftRS      /1.0d-3/
      real*8 gNMDA_tuftRS_to_tuftRS      /0.10d-3/
      real*8 gAMPA_tuftRS_to_deepbask    /3.0d-3/
      real*8 gNMDA_tuftRS_to_deepbask    /0.10d-3/
c     real*8 gAMPA_tuftRS_to_deepng      /2.0d-3/
      real*8 gAMPA_tuftRS_to_deepng      /0.8d-3/
      real*8 gNMDA_tuftRS_to_deepng      /0.10d-3/
      real*8 gAMPA_tuftRS_to_deepaxax    /3.0d-3/
      real*8 gNMDA_tuftRS_to_deepaxax    /0.10d-3/
      real*8 gAMPA_tuftRS_to_deepLTS     /1.0d-3/
      real*8 gNMDA_tuftRS_to_deepLTS     /0.05d-3/
      real*8 gAMPA_tuftRS_to_nontuftRS   /0.1d-3/
      real*8 gNMDA_tuftRS_to_nontuftRS   /0.01d-3/

!     real*8 gGABA_deepbask_to_spinstell /1.0d-3/
      real*8 gGABA_deepbask_to_spinstell /1.50d-3/ ! ? suppress spiny stellate bursts ?
c     real*8 gGABA_deepbask_to_tuftIB    /0.7d-3/
      real*8 gGABA_deepbask_to_tuftIB    /0.3d-3/
      real*8 gGABA_deepbask_to_tuftRS    /0.7d-3/
      real*8 gGABA_deepbask_to_deepbask  /0.2d-3/
c     real*8 gGABA_deepbask_to_deepng    /0.2d-3/
      real*8 gGABA_deepbask_to_deepng    /0.1d-3/
      real*8 gGABA_deepbask_to_deepaxax  /0.2d-3/
      real*8 gGABA_deepbask_to_deepLTS   /0.7d-3/
      real*8 gGABA_deepbask_to_nontuftRS /0.1d-3/

c     real*8 gGABA_deepng_to_tuftIB      /0.8d-3/
      real*8 gGABA_deepng_to_tuftIB      /0.3d-3/
      real*8 gGABA_deepng_to_tuftRS      /0.8d-3/
      real*8 gGABA_deepng_to_nontuftRS   /0.1d-3/
      real*8 gGABA_deepng_to_spinstell   /0.8d-3/
c     real*8 gGABA_deepng_to_deepng      /0.2d-3/
      real*8 gGABA_deepng_to_deepng      /0.1d-3/
      real*8 gGABA_deepng_to_deepbask    /0.2d-3/

c     real*8 gGABAB_deepng_to_tuftIB      /0.015d-3/
!     real*8 gGABAB_deepng_to_tuftIB      /0.030d-3/
      real*8 gGABAB_deepng_to_tuftIB      /0.040d-3/
      real*8 gGABAB_deepng_to_tuftRS      /0.025d-3/
      real*8 gGABAB_deepng_to_nontuftRS   /0.0003d-3/
      real*8 gGABAB_deepng_to_spinstell   /0.025d-3/

      real*8 gGABA_deepaxax_to_suppyrRS   /0.0d-3/
      real*8 gGABA_deepaxax_to_suppyrFRB  /0.0d-3/
!     real*8 gGABA_deepaxax_to_spinstell  /1.0d-3/
      real*8 gGABA_deepaxax_to_spinstell  /1.5d-3/ ! ? suppress spiny stellate bursts ?
      real*8 gGABA_deepaxax_to_tuftIB     /1.0d-3/
      real*8 gGABA_deepaxax_to_tuftRS     /1.0d-3/
      real*8 gGABA_deepaxax_to_nontuftRS  /0.05d-3/

      real*8 gGABA_deepLTS_to_suppyrRS    /.00d-3/
      real*8 gGABA_deepLTS_to_suppyrFRB   /.00d-3/
      real*8 gGABA_deepLTS_to_supbask     /.01d-3/
      real*8 gGABA_deepLTS_to_supaxax     /.01d-3/
      real*8 gGABA_deepLTS_to_supLTS      /.05d-3/
      real*8 gGABA_deepLTS_to_spinstell   /.01d-3/
!     real*8 gGABA_deepLTS_to_tuftIB      /.02d-3/
      real*8 gGABA_deepLTS_to_tuftIB      /.05d-3/ ! will this help suppress bursting?
      real*8 gGABA_deepLTS_to_tuftRS      /.02d-3/
      real*8 gGABA_deepLTS_to_deepbask    /.01d-3/
      real*8 gGABA_deepLTS_to_deepaxax    /.01d-3/
      real*8 gGABA_deepLTS_to_deepLTS     /.05d-3/
c     real*8 gGABA_deepLTS_to_nontuftRS   /.20d-3/
      real*8 gGABA_deepLTS_to_nontuftRS   /.02d-3/

      real*8 gAMPA_TCR_to_suppyrRS        /0.5d-3/
      real*8 gNMDA_TCR_to_suppyrRS        /0.05d-3/
      real*8 gAMPA_TCR_to_suppyrFRB       /0.5d-3/
      real*8 gNMDA_TCR_to_suppyrFRB       /0.05d-3/
!     real*8 gAMPA_TCR_to_supbask         /1.0d-3/
      real*8 gAMPA_TCR_to_supbask         /0.1d-3/
! try a variation in which main feedforward inhibtion from thalamus
! is via deep interneurons.  May be necessary later to include special
! layer 4 interneurons
!     real*8 gNMDA_TCR_to_supbask         /.10d-3/
c     real*8 gNMDA_TCR_to_supbask         /.01d-3/
      real*8 gNMDA_TCR_to_supbask         /.00d-3/
      real*8 gAMPA_TCR_to_supng           /0.1d-3/
      real*8 gNMDA_TCR_to_supng           /0.0d-3/
!     real*8 gAMPA_TCR_to_supaxax         /1.0d-3/
      real*8 gAMPA_TCR_to_supaxax         /0.1d-3/
!     real*8 gNMDA_TCR_to_supaxax         /.10d-3/
      real*8 gNMDA_TCR_to_supaxax         /.00d-3/
      real*8 gAMPA_TCR_to_spinstell       /1.0d-3/
      real*8 gNMDA_TCR_to_spinstell       /.10d-3/
      real*8 gAMPA_TCR_to_tuftIB          /1.5d-3/
      real*8 gNMDA_TCR_to_tuftIB          /.15d-3/
      real*8 gAMPA_TCR_to_tuftRS          /1.5d-3/
      real*8 gNMDA_TCR_to_tuftRS          /.15d-3/
!     real*8 gAMPA_TCR_to_deepbask        /1.0d-3/
      real*8 gAMPA_TCR_to_deepbask        /1.5d-3/
!     real*8 gAMPA_TCR_to_deepbask        /0.0d-3/ ! try for very fast FF excit.
      real*8 gNMDA_TCR_to_deepbask        /.10d-3/
      real*8 gAMPA_TCR_to_deepng          /1.5d-3/
      real*8 gNMDA_TCR_to_deepng          /0.1d-3/
      real*8 gAMPA_TCR_to_deepaxax        /1.0d-3/
!     real*8 gAMPA_TCR_to_deepaxax        /0.0d-3/ ! try for very fast FF excit.
      real*8 gNMDA_TCR_to_deepaxax        /.10d-3/
      real*8 gAMPA_TCR_to_nRT             /0.75d-3/   
      real*8 gNMDA_TCR_to_nRT             /.15d-3/
      real*8 gAMPA_TCR_to_nontuftRS       /0.0d-3/    
      real*8 gNMDA_TCR_to_nontuftRS       /.00d-3/

      real*8 gGABAB_nRT_to_TCR            /0.02d-3/
!     real*8 gGABA_nRT_to_TCR             /1.0d-3/
      real*8 gGABA_nRT_to_TCR(num_nRT)
! Values here need to be set below  
      real*8 gGABA_nRT_to_nRT             /0.30d-3/
      real*8 gGABAB_nRT_to_nRT            /0.020d-3/

c     real*8 gAMPA_nontuftRS_to_suppyrRS  /0.2d-3/
      real*8 gAMPA_nontuftRS_to_suppyrRS  /5.0d-3/
      real*8 gNMDA_nontuftRS_to_suppyrRS  /0.05d-3/
      real*8 gAMPA_nontuftRS_to_suppyrFRB /0.5d-3/
      real*8 gNMDA_nontuftRS_to_suppyrFRB /0.05d-3/
      real*8 gAMPA_nontuftRS_to_supbask   /1.0d-3/
c     real*8 gNMDA_nontuftRS_to_supbask   /0.1d-3/
      real*8 gNMDA_nontuftRS_to_supbask   /0.0d-3/
      real*8 gAMPA_nontuftRS_to_supaxax   /1.0d-3/
c     real*8 gNMDA_nontuftRS_to_supaxax   /0.1d-3/
      real*8 gNMDA_nontuftRS_to_supaxax   /0.0d-3/
      real*8 gAMPA_nontuftRS_to_supLTS    /1.0d-3/
c     real*8 gNMDA_nontuftRS_to_supLTS    /0.1d-3/
      real*8 gNMDA_nontuftRS_to_supLTS    /0.0d-3/
      real*8 gAMPA_nontuftRS_to_spinstell /0.5d-3/
      real*8 gNMDA_nontuftRS_to_spinstell /0.05d-3/
      real*8 gAMPA_nontuftRS_to_tuftIB    /1.0d-3/
      real*8 gNMDA_nontuftRS_to_tuftIB    /0.1d-3/
      real*8 gAMPA_nontuftRS_to_tuftRS    /1.0d-3/
      real*8 gNMDA_nontuftRS_to_tuftRS    /0.1d-3/
      real*8 gAMPA_nontuftRS_to_deepbask  /3.0d-3/
      real*8 gNMDA_nontuftRS_to_deepbask  /.10d-3/
c     real*8 gAMPA_nontuftRS_to_deepng    /2.0d-3/
      real*8 gAMPA_nontuftRS_to_deepng    /0.8d-3/
      real*8 gNMDA_nontuftRS_to_deepng    /.10d-3/
      real*8 gAMPA_nontuftRS_to_deepaxax  /3.0d-3/
      real*8 gNMDA_nontuftRS_to_deepaxax  /.00d-3/
      real*8 gAMPA_nontuftRS_to_deepLTS   /1.0d-3/
      real*8 gNMDA_nontuftRS_to_deepLTS   /.10d-3/
      real*8 gAMPA_nontuftRS_to_TCR       /.15d-3/ ! make this small
      real*8 gNMDA_nontuftRS_to_TCR       /.015d-3/
      real*8 gAMPA_nontuftRS_to_nRT       /0.5d-3/
      real*8 gNMDA_nontuftRS_to_nRT       /0.05d-3/
c     real*8 gAMPA_nontuftRS_to_nontuftRS /1.5d-3/
      real*8 gAMPA_nontuftRS_to_nontuftRS /3.0d-3/
      real*8 gNMDA_nontuftRS_to_nontuftRS /0.01d-3/
c End defining synaptic conductance scaling factors

c Begin definition of compartments where synaptic connections
c can form.
       INTEGER compallow_suppyrRS_to_suppyrRS 
     &  (ncompallow_suppyrRS_to_suppyrRS)
     &  /2,3,4,5,6,7,8,9,14,15,16,17,18,19,20,21,26,
     & 27,28,29,30,31,32,33,10,11,12,13,22,23,24,25,
     & 34,35,36,37/
       INTEGER compallow_suppyrRS_to_suppyrFRB
     &  (ncompallow_suppyrRS_to_suppyrFRB)
     &  /2,3,4,5,6,7,8,9,14,15,16,17,18,19,20,21,26,
     & 27,28,29,30,31,32,33,10,11,12,13,22,23,24,25,
     & 34,35,36,37/
       INTEGER compallow_suppyrRS_to_supbask  
     &  (ncompallow_suppyrRS_to_supbask  )
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_suppyrRS_to_supng    
     &  (ncompallow_suppyrRS_to_supng    )
     &  /2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,
     &  21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,
     &  37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,52,53/
       INTEGER compallow_suppyrRS_to_supaxax  
     &  (ncompallow_suppyrRS_to_supaxax  )
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_suppyrRS_to_supLTS   
     &  (ncompallow_suppyrRS_to_supLTS   )
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_suppyrRS_to_spinstell
     &  (ncompallow_suppyrRS_to_spinstell)
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_suppyrRS_to_tuftIB   
     &  (ncompallow_suppyrRS_to_tuftIB   )
     &  /39,40,41,42,43,44,45,46/
       INTEGER compallow_suppyrRS_to_tuftRS   
     &  (ncompallow_suppyrRS_to_tuftRS   )
     &  /39,40,41,42,43,44,45,46/
       INTEGER compallow_suppyrRS_to_deepbask 
     &  (ncompallow_suppyrRS_to_deepbask )
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_suppyrRS_to_deepaxax 
     &  (ncompallow_suppyrRS_to_deepaxax )
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_suppyrRS_to_deepLTS  
     &  (ncompallow_suppyrRS_to_deepLTS  )
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_suppyrRS_to_nontuftRS
     &  (ncompallow_suppyrRS_to_nontuftRS)
     &  /38,39,40,41,42,43,44/

       INTEGER compallow_suppyrFRB_to_suppyrRS 
     &  (ncompallow_suppyrFRB_to_suppyrRS)
     &  /2,3,4,5,6,7,8,9,14,15,16,17,18,19,20,21,26,
     & 27,28,29,30,31,32,33,10,11,12,13,22,23,24,25,
     & 34,35,36,37/
       INTEGER compallow_suppyrFRB_to_suppyrFRB
     &  (ncompallow_suppyrFRB_to_suppyrFRB)
     &  /2,3,4,5,6,7,8,9,14,15,16,17,18,19,20,21,26,
     & 27,28,29,30,31,32,33,10,11,12,13,22,23,24,25,
     & 34,35,36,37/
       INTEGER compallow_suppyrFRB_to_supbask  
     &  (ncompallow_suppyrFRB_to_supbask  )
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_suppyrFRB_to_supng    
     &  (ncompallow_suppyrFRB_to_supng    )
     &  /2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,
     &  21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,
     &  37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,52,53/
       INTEGER compallow_suppyrFRB_to_supaxax  
     &  (ncompallow_suppyrFRB_to_supaxax  )
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_suppyrFRB_to_supLTS   
     &  (ncompallow_suppyrFRB_to_supLTS   )
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_suppyrFRB_to_spinstell
     &  (ncompallow_suppyrFRB_to_spinstell)
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_suppyrFRB_to_tuftIB   
     &  (ncompallow_suppyrFRB_to_tuftIB   )
     &  /39,40,41,42,43,44,45,46/
       INTEGER compallow_suppyrFRB_to_tuftRS   
     &  (ncompallow_suppyrFRB_to_tuftRS   )
     &  /39,40,41,42,43,44,45,46/
       INTEGER compallow_suppyrFRB_to_deepbask 
     &  (ncompallow_suppyrFRB_to_deepbask )
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_suppyrFRB_to_deepaxax 
     &  (ncompallow_suppyrFRB_to_deepaxax )
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_suppyrFRB_to_deepLTS  
     &  (ncompallow_suppyrFRB_to_deepLTS  )
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_suppyrFRB_to_nontuftRS
     &  (ncompallow_suppyrFRB_to_nontuftRS)
     &  /38,39,40,41,42,43,44/

       INTEGER compallow_supbask_to_suppyrRS
     &  (ncompallow_supbask_to_suppyrRS)
     & /1,2,3,4,5,6,7,8,9,38,39/
       INTEGER compallow_supbask_to_suppyrFRB
     &  (ncompallow_supbask_to_suppyrFRB)
     & /1,2,3,4,5,6,7,8,9,38,39/
       INTEGER compallow_supbask_to_supbask  
     &  (ncompallow_supbask_to_supbask  )
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_supbask_to_supng    
     &  (ncompallow_supbask_to_supng    )
     & /2,15,28,41/
       INTEGER compallow_supbask_to_supaxax  
     &  (ncompallow_supbask_to_supaxax  )
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_supbask_to_supLTS   
     &  (ncompallow_supbask_to_supLTS   )
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_supbask_to_spinstell
     &  (ncompallow_supbask_to_spinstell)
     &  /1,2,15,28,41/

       INTEGER compallow_supng_to_suppyrRS 
     &  (ncompallow_supng_to_suppyrRS )
     & /2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,
     & 21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,
     & 41,42,43,44,45,46,47,48,49,50,51,52,53,54,55,56,57,
     & 58,59,60,61,62,63,64,65,66,67,68/
       INTEGER compallow_supng_to_suppyrFRB
     &  (ncompallow_supng_to_suppyrFRB)
     & /2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,
     & 21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,
     & 41,42,43,44,45,46,47,48,49,50,51,52,53,54,55,56,57,
     & 58,59,60,61,62,63,64,65,66,67,68/
       INTEGER compallow_supng_to_nontuftRS
     &  (ncompallow_supng_to_nontuftRS)
     & /40,41,42,43,44/
       INTEGER compallow_supng_to_tuftIB   
     &  (ncompallow_supng_to_tuftIB   )
     & /42,43,44,45,46,47,48,49,50,51,52,53,54,55/
       INTEGER compallow_supng_to_tuftRS   
     &  (ncompallow_supng_to_tuftRS   )
     & /42,43,44,45,46,47,48,49,50,51,52,53,54,55/
       INTEGER compallow_supng_to_supng    
     &  (ncompallow_supng_to_supng    )
     & /2,1,28,41/
       INTEGER compallow_supng_to_supbask  
     &  (ncompallow_supng_to_supbask  )
     & /2,1,28,41/

       INTEGER compallow_supLTS_to_suppyrRS
     &  (ncompallow_supLTS_to_suppyrRS)
     & /14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,
     &  31,32,33,34,35,36,37,40,41,42,43,44,45,46,47,48,49,
     &  50,51,52,53,54,55,56,57,58,59,60,61,62,63,64,65,66,
     &  67,68/
       INTEGER compallow_supLTS_to_suppyrFRB
     &  (ncompallow_supLTS_to_suppyrFRB)
     & /14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,
     &  31,32,33,34,35,36,37,40,41,42,43,44,45,46,47,48,49,
     &  50,51,52,53,54,55,56,57,58,59,60,61,62,63,64,65,66,
     &  67,68/
       INTEGER compallow_supLTS_to_supbask  
     &  (ncompallow_supLTS_to_supbask)  
     & /5,6,7,8,9,10,11,12,13,14,18,19,20,21,22,23,24,25,
     &  26,27,31,32,33,34,35,36,37,38,39,40,
     &  44,45,46,47,48,49,50,51,52,53/
       INTEGER compallow_supLTS_to_supaxax  
     &  (ncompallow_supLTS_to_supaxax)  
     & /5,6,7,8,9,10,11,12,13,14,18,19,20,21,22,23,24,25,
     &  26,27,31,32,33,34,35,36,37,38,39,40,
     &  44,45,46,47,48,49,50,51,52,53/
       INTEGER compallow_supLTS_to_supLTS   
     &  (ncompallow_supLTS_to_supLTS )  
     & /5,6,7,8,9,10,11,12,13,14,18,19,20,21,22,23,24,25,
     &  26,27,31,32,33,34,35,36,37,38,39,40,
     &  44,45,46,47,48,49,50,51,52,53/
       INTEGER compallow_supLTS_to_spinstell
     &  (ncompallow_supLTS_to_spinstell)
     & /5,6,7,8,9,10,11,12,13,14,18,19,20,21,22,23,24,25,
     &  26,27,31,32,33,34,35,36,37,38,39,40,
     &  44,45,46,47,48,49,50,51,52,53/
       INTEGER compallow_supLTS_to_tuftIB   
     &  (ncompallow_supLTS_to_tuftIB   )
     & / 13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,
     &   29,30,31,32,33,34,38,39,40,41,42,43,44,45,46,47,
     &   48,49,50,51,52,53,54,55/
       INTEGER compallow_supLTS_to_tuftRS   
     &  (ncompallow_supLTS_to_tuftRS   )
     & / 13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,
     &   29,30,31,32,33,34,38,39,40,41,42,43,44,45,46,47,
     &   48,49,50,51,52,53,54,55/
       INTEGER compallow_supLTS_to_deepbask 
     &  (ncompallow_supLTS_to_deepbask )
     & / 8,9,10,11,12,21,22,23,24,25,34,35,36,37,38,
     &   47,48,49,50,51/ 
       INTEGER compallow_supLTS_to_deepaxax 
     &  (ncompallow_supLTS_to_deepaxax )
     & / 8,9,10,11,12,21,22,23,24,25,34,35,36,37,38,
     &   47,48,49,50,51/ 
       INTEGER compallow_supLTS_to_deepLTS  
     &  (ncompallow_supLTS_to_deepLTS  )
     & / 8,9,10,11,12,21,22,23,24,25,34,35,36,37,38,
     &   47,48,49,50,51/ 
       INTEGER compallow_supLTS_to_nontuftRS
     &  (ncompallow_supLTS_to_nontuftRS)
     & / 13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,
     &   29,30,31,32,33,34,38,39,40,41,42,43,44/ 

c      INTEGER compallow_spinstell_to_suppyrRS
c    &   (ncompallow_spinstell_to_suppyrRS)
c    & / 40,41,42,43,44,45,46,47,48,49,50,51,52/
c      INTEGER compallow_spinstell_to_suppyrFRB
c    &   (ncompallow_spinstell_to_suppyrFRB)
c    & / 40,41,42,43,44,45,46,47,48,49,50,51,52/
! 3 Mar. 2004: Feldmeyer, ..., Sakmann, J Physiol 2002 assert
! that in barrel ctx, spiny stellates go to basal dendrites of
! layer 2/3 pyramids
       INTEGER compallow_spinstell_to_suppyrRS
     &   (ncompallow_spinstell_to_suppyrRS)
     & /  2, 3, 4, 5, 6, 7, 8, 9,14,15,16,17,18,19,20,21,
     &   26,27,28,29,30,31,32,33/
       INTEGER compallow_spinstell_to_suppyrFRB
     &   (ncompallow_spinstell_to_suppyrFRB)
     & /  2, 3, 4, 5, 6, 7, 8, 9,14,15,16,17,18,19,20,21,
     &   26,27,28,29,30,31,32,33/
       INTEGER compallow_spinstell_to_supbask  
     &   (ncompallow_spinstell_to_supbask  )
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_spinstell_to_supaxax  
     &   (ncompallow_spinstell_to_supaxax  )
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_spinstell_to_supLTS   
     &   (ncompallow_spinstell_to_supLTS   )
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_spinstell_to_spinstell
     &   (ncompallow_spinstell_to_spinstell)
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_spinstell_to_tuftIB   
     &   (ncompallow_spinstell_to_tuftIB   )
     &  / 7,8,9,10,11,12,36,37,38,39,40,41/
       INTEGER compallow_spinstell_to_tuftRS   
     &   (ncompallow_spinstell_to_tuftRS   )
     &  / 7,8,9,10,11,12,36,37,38,39,40,41/
       INTEGER compallow_spinstell_to_deepbask 
     &   (ncompallow_spinstell_to_deepbask )
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_spinstell_to_deepng   
     &   (ncompallow_spinstell_to_deepng   )
     &  /2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,
     &  21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,
     &  37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,52,53/
       INTEGER compallow_spinstell_to_deepaxax 
     &   (ncompallow_spinstell_to_deepaxax )
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_spinstell_to_deepLTS  
     &   (ncompallow_spinstell_to_deepLTS  )
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_spinstell_to_nontuftRS
     &   (ncompallow_spinstell_to_nontuftRS)
     &  / 37,38,39,40,41/

       INTEGER compallow_tuftIB_to_suppyrRS
     &   (ncompallow_tuftIB_to_suppyrRS)
     & / 40,41,42,43,44,45,46,47,48,49,50,51,52/
       INTEGER compallow_tuftIB_to_suppyrFRB
     &   (ncompallow_tuftIB_to_suppyrFRB)
     & / 40,41,42,43,44,45,46,47,48,49,50,51,52/
       INTEGER compallow_tuftIB_to_supbask  
     &   (ncompallow_tuftIB_to_supbask)  
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_tuftIB_to_supaxax  
     &   (ncompallow_tuftIB_to_supaxax)  
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_tuftIB_to_supLTS   
     &   (ncompallow_tuftIB_to_supLTS )  
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_tuftIB_to_spinstell
     &   (ncompallow_tuftIB_to_spinstell) 
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_tuftIB_to_tuftIB   
     &   (ncompallow_tuftIB_to_tuftIB)    
     &  / 2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,
     &   21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,
     &   38,39,40,41,42,43,44,45,46,47/
       INTEGER compallow_tuftIB_to_tuftRS   
     &   (ncompallow_tuftIB_to_tuftRS)    
     &  / 2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,
     &   21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,
     &   38,39,40,41,42,43,44,45,46,47/
       INTEGER compallow_tuftIB_to_deepbask 
     &   (ncompallow_tuftIB_to_deepbask)  
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_tuftIB_to_deepng   
     &   (ncompallow_tuftIB_to_deepng  )  
     &  /2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,
     &  21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,
     &  37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,52,53/
       INTEGER compallow_tuftIB_to_deepaxax 
     &   (ncompallow_tuftIB_to_deepaxax)  
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_tuftIB_to_deepLTS  
     &   (ncompallow_tuftIB_to_deepLTS )  
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_tuftIB_to_nontuftRS
     &   (ncompallow_tuftIB_to_nontuftRS) 
     &  /2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,
     &   21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,
     &   37,38,39,40,41,42,43,44/

       INTEGER compallow_tuftRS_to_suppyrRS
     &   (ncompallow_tuftRS_to_suppyrRS)
     & / 40,41,42,43,44,45,46,47,48,49,50,51,52/
       INTEGER compallow_tuftRS_to_suppyrFRB
     &   (ncompallow_tuftRS_to_suppyrFRB)
     & / 40,41,42,43,44,45,46,47,48,49,50,51,52/
       INTEGER compallow_tuftRS_to_supbask  
     &   (ncompallow_tuftRS_to_supbask)  
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_tuftRS_to_supaxax  
     &   (ncompallow_tuftRS_to_supaxax)  
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_tuftRS_to_supLTS   
     &   (ncompallow_tuftRS_to_supLTS )  
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_tuftRS_to_spinstell
     &   (ncompallow_tuftRS_to_spinstell) 
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_tuftRS_to_tuftIB   
     &   (ncompallow_tuftRS_to_tuftIB)    
     &  / 2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,
     &   21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,
     &   38,39,40,41,42,43,44,45,46,47/
       INTEGER compallow_tuftRS_to_tuftRS   
     &   (ncompallow_tuftRS_to_tuftRS)    
     &  / 2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,
     &   21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,
     &   38,39,40,41,42,43,44,45,46,47/
       INTEGER compallow_tuftRS_to_deepbask 
     &   (ncompallow_tuftRS_to_deepbask)  
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_tuftRS_to_deepng   
     &   (ncompallow_tuftRS_to_deepng  )  
     &  /2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,
     &  21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,
     &  37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,52,53/
       INTEGER compallow_tuftRS_to_deepaxax 
     &   (ncompallow_tuftRS_to_deepaxax)  
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_tuftRS_to_deepLTS  
     &   (ncompallow_tuftRS_to_deepLTS )  
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_tuftRS_to_nontuftRS
     &   (ncompallow_tuftRS_to_nontuftRS) 
     &  /2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,
     &   21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,
     &   37,38,39,40,41,42,43,44/

       INTEGER compallow_deepbask_to_spinstell
     &   (ncompallow_deepbask_to_spinstell)
     &  /1,2,15,28,41/
       INTEGER compallow_deepbask_to_tuftIB   
     &   (ncompallow_deepbask_to_tuftIB)   
     & / 1,2,3,4,5,6,35,36/
       INTEGER compallow_deepbask_to_tuftRS   
     &   (ncompallow_deepbask_to_tuftRS)   
     & / 1,2,3,4,5,6,35,36/
       INTEGER compallow_deepbask_to_deepbask 
     &   (ncompallow_deepbask_to_deepbask) 
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_deepbask_to_deepng   
     &   (ncompallow_deepbask_to_deepng  ) 
     &  /2,15,28,41/
       INTEGER compallow_deepbask_to_deepaxax 
     &   (ncompallow_deepbask_to_deepaxax) 
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_deepbask_to_deepLTS  
     &   (ncompallow_deepbask_to_deepLTS)  
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
       INTEGER compallow_deepbask_to_nontuftRS
     &   (ncompallow_deepbask_to_nontuftRS)
     &  /1,2,3,4,5,6,35,36/

       INTEGER compallow_deepng_to_tuftIB    
     &  (ncompallow_deepng_to_tuftIB   )
     & /2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,
     &  21,22,23,24,25,26,27,28,29,30,31,32,33,34/
       INTEGER compallow_deepng_to_tuftRS    
     &  (ncompallow_deepng_to_tuftRS   )
     & /2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,
     &  21,22,23,24,25,26,27,28,29,30,31,32,33,34/
       INTEGER compallow_deepng_to_nontuftRS 
     &  (ncompallow_deepng_to_nontuftRS)
     & /2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,
     &  21,22,23,24,25,26,27,28,29,30,31,32,33,34/
       INTEGER compallow_deepng_to_spinstell 
     &  (ncompallow_deepng_to_spinstell)
     &  /2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,
     &  21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,
     &  37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,52,53/
       INTEGER compallow_deepng_to_deepng    
     &  (ncompallow_deepng_to_deepng   )
     &  /2,15,28,41/
       INTEGER compallow_deepng_to_deepbask  
     &  (ncompallow_deepng_to_deepbask )
     &  /2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,
     &  21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,
     &  37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,52,53/

       INTEGER compallow_deepLTS_to_suppyrRS
     &   (ncompallow_deepLTS_to_suppyrRS)
     & /14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,
     &  31,32,33,34,35,36,37,40,41,42,43,44,45,46,47,48,49,
     &  50,51,52,53,54,55,56,57,58,59,60,61,62,63,64,65,66,
     &  67,68/
       INTEGER compallow_deepLTS_to_suppyrFRB
     &   (ncompallow_deepLTS_to_suppyrFRB)
     & /14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,
     &  31,32,33,34,35,36,37,40,41,42,43,44,45,46,47,48,49,
     &  50,51,52,53,54,55,56,57,58,59,60,61,62,63,64,65,66,
     &  67,68/
       INTEGER compallow_deepLTS_to_supbask  
     &   (ncompallow_deepLTS_to_supbask)  
     & / 8,9,10,11,12,21,22,23,24,25,34,35,36,37,38,
     &   47,48,49,50,51/ 
       INTEGER compallow_deepLTS_to_supaxax  
     &   (ncompallow_deepLTS_to_supaxax)  
     & / 8,9,10,11,12,21,22,23,24,25,34,35,36,37,38,
     &   47,48,49,50,51/ 
       INTEGER compallow_deepLTS_to_supLTS   
     &   (ncompallow_deepLTS_to_supLTS)   
     & / 8,9,10,11,12,21,22,23,24,25,34,35,36,37,38,
     &   47,48,49,50,51/ 
       INTEGER compallow_deepLTS_to_spinstell
     &   (ncompallow_deepLTS_to_spinstell)
     & /5,6,7,8,9,10,11,12,13,14,18,19,20,21,22,23,24,25,
     &  26,27,31,32,33,34,35,36,37,38,39,40,
     &  44,45,46,47,48,49,50,51,52,53/
       INTEGER compallow_deepLTS_to_tuftIB   
     &   (ncompallow_deepLTS_to_tuftIB)    
     & / 13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,
     &   29,30,31,32,33,34,38,39,40,41,42,43,44,45,46,47,
     &   48,49,50,51,52,53,54,55/
       INTEGER compallow_deepLTS_to_tuftRS   
     &   (ncompallow_deepLTS_to_tuftRS)    
     & / 13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,
     &   29,30,31,32,33,34,38,39,40,41,42,43,44,45,46,47,
     &   48,49,50,51,52,53,54,55/
       INTEGER compallow_deepLTS_to_deepbask 
     &   (ncompallow_deepLTS_to_deepbask)  
     & /5,6,7,8,9,10,11,12,13,14,18,19,20,21,22,23,24,25,
     &  26,27,31,32,33,34,35,36,37,38,39,40,
     &  44,45,46,47,48,49,50,51,52,53/
       INTEGER compallow_deepLTS_to_deepaxax 
     &   (ncompallow_deepLTS_to_deepaxax)  
     & /5,6,7,8,9,10,11,12,13,14,18,19,20,21,22,23,24,25,
     &  26,27,31,32,33,34,35,36,37,38,39,40,
     &  44,45,46,47,48,49,50,51,52,53/
       INTEGER compallow_deepLTS_to_deepLTS  
     &   (ncompallow_deepLTS_to_deepLTS)   
     & /5,6,7,8,9,10,11,12,13,14,18,19,20,21,22,23,24,25,
     &  26,27,31,32,33,34,35,36,37,38,39,40,
     &  44,45,46,47,48,49,50,51,52,53/
       INTEGER compallow_deepLTS_to_nontuftRS
     &   (ncompallow_deepLTS_to_nontuftRS) 
     & / 13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,
     &   29,30,31,32,33,34,38,39,40,41,42,43,44/ 

       INTEGER compallow_TCR_to_suppyrRS
     &   (ncompallow_TCR_to_suppyrRS)
     &  /45,46,47,48,49,50,51,52,53,54,55,56,57,58,59,60,
     &   61,62,63,64,65,66,67,68/
       INTEGER compallow_TCR_to_suppyrFRB
     &   (ncompallow_TCR_to_suppyrFRB)
     &  /45,46,47,48,49,50,51,52,53,54,55,56,57,58,59,60,
     &   61,62,63,64,65,66,67,68/
       INTEGER compallow_TCR_to_supbask  
     &   (ncompallow_TCR_to_supbask)  
     &  /2,3,4,15,16,17,28,29,30,41,42,43/
       INTEGER compallow_TCR_to_supng    
     &   (ncompallow_TCR_to_supng  )  
     &  /2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,
     &  21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,
     &  37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,52,53/
       INTEGER compallow_TCR_to_supaxax  
     &   (ncompallow_TCR_to_supaxax)  
     &  /2,3,4,15,16,17,28,29,30,41,42,43/
       INTEGER compallow_TCR_to_spinstell
     &   (ncompallow_TCR_to_spinstell)
     &  /2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,
     &   21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,
     &   37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,52,53/
       INTEGER compallow_TCR_to_tuftIB   
     &   (ncompallow_TCR_to_tuftIB)   
     &  / 47,48,49,50,51,52,53,54,55/
       INTEGER compallow_TCR_to_tuftRS   
     &   (ncompallow_TCR_to_tuftRS)   
     &  / 47,48,49,50,51,52,53,54,55/
       INTEGER compallow_TCR_to_deepbask 
     &   (ncompallow_TCR_to_deepbask) 
!    &  /2,3,4,15,16,17,28,29,30,41,42,43/
     &  /1,2,15,28,41/  ! soma & proximal dendrites
       INTEGER compallow_TCR_to_deepng   
     &   (ncompallow_TCR_to_deepng  ) 
     &  /2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,
     &  21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,
     &  37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,52,53/
       INTEGER compallow_TCR_to_deepaxax 
     &   (ncompallow_TCR_to_deepaxax) 
!    &  /2,3,4,15,16,17,28,29,30,41,42,43/
     &  /1,2,15,28,41/  ! soma & proximal dendrites
       INTEGER compallow_TCR_to_nRT      
     &   (ncompallow_TCR_to_nRT)      
     &  /2,3,4,15,16,17,28,29,30,41,42,43/
       INTEGER compallow_TCR_to_nontuftRS
     &   (ncompallow_TCR_to_nontuftRS)
     &  /40,41,42,43,44/

       INTEGER compallow_nRT_to_TCR
     &   (ncompallow_nRT_to_TCR)
     &  /1,2,15,28,41,54,67,80,93,106,119/
       INTEGER compallow_nRT_to_nRT
     &   (ncompallow_nRT_to_nRT)
     &  /1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,
     &   20,21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,
     &   36,37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,
     &   52,53/

        INTEGER compallow_nontuftRS_to_suppyrRS
     &    (ncompallow_nontuftRS_to_suppyrRS)
     &   / 41,42,43,44 /
        INTEGER compallow_nontuftRS_to_suppyrFRB
     &    (ncompallow_nontuftRS_to_suppyrFRB)
     &   / 41,42,43,44 /
        INTEGER compallow_nontuftRS_to_supbask  
     &    (ncompallow_nontuftRS_to_supbask)  
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
        INTEGER compallow_nontuftRS_to_supaxax  
     &    (ncompallow_nontuftRS_to_supaxax)  
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
        INTEGER compallow_nontuftRS_to_supLTS   
     &    (ncompallow_nontuftRS_to_supLTS)   
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
        INTEGER compallow_nontuftRS_to_spinstell
     &    (ncompallow_nontuftRS_to_spinstell)
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
        INTEGER compallow_nontuftRS_to_tuftIB   
     &    (ncompallow_nontuftRS_to_tuftIB)   
     &  / 2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,
     &   21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,
     &   38,39,40,41,42,43,44,45,46,47/
        INTEGER compallow_nontuftRS_to_tuftRS   
     &    (ncompallow_nontuftRS_to_tuftRS)   
     &  / 2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,
     &   21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,
     &   38,39,40,41,42,43,44,45,46,47/
        INTEGER compallow_nontuftRS_to_deepbask 
     &    (ncompallow_nontuftRS_to_deepbask) 
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
        INTEGER compallow_nontuftRS_to_deepng   
     &    (ncompallow_nontuftRS_to_deepng  ) 
     &  /2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,
     &  21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,
     &  37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,52,53/
        INTEGER compallow_nontuftRS_to_deepaxax 
     &    (ncompallow_nontuftRS_to_deepaxax) 
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
        INTEGER compallow_nontuftRS_to_deepLTS  
     &    (ncompallow_nontuftRS_to_deepLTS)  
     &  /5,6,7,8,9,10,18,19,20,21,22,23,31,32,33,34,35,36,
     &   44,45,46,47,48,49/
        INTEGER compallow_nontuftRS_to_TCR      
     &    (ncompallow_nontuftRS_to_TCR)      
     &  /  6,  7,  8,  9, 10, 11, 12, 13, 14,
     &    19, 20, 21, 22, 23, 24, 25, 26, 27,
     &    32, 33, 34, 35, 36, 37, 38, 39, 40,
     &    45, 46, 47, 48, 49, 50, 51, 52, 53,
     &    58, 59, 60, 61, 62, 63, 64, 65, 66,
     &    71, 72, 73, 74, 75, 76, 77, 78, 79,
     &    84, 85, 86, 87, 88, 89, 90, 91, 92,
     &    97, 98, 99,100,101,102,103,104,105,
     &   110,111,112,113,114,115,116,117,118,
     &   123,124,125,126,127,128,129,130,131/
        INTEGER compallow_nontuftRS_to_nRT      
     &    (ncompallow_nontuftRS_to_nRT)      
     & / 2,3,4,15,16,17,28,29,30,41,42,43/
        INTEGER compallow_nontuftRS_to_nontuftRS
     &    (ncompallow_nontuftRS_to_nontuftRS)
     &  /2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,
     &   21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,
     &   37,38,39,40,41,42,43,44/


c Maps of synaptic connectivity.  For simplicity, all contacts
c only made to one compartment.  Axoaxonic cells forced to contact 
c initial axon segments; other compartments will be listed in arrays.
        INTEGER 
     & map_suppyrRS_to_suppyrRS(num_suppyrRS_to_suppyrRS,
     &                           num_suppyrRS),
     & map_suppyrRS_to_suppyrFRB(num_suppyrRS_to_suppyrFRB,
     &                           num_suppyrFRB),
     & map_suppyrRS_to_supbask(num_suppyrRS_to_supbask,  
     &                           num_supbask), 
     & map_suppyrRS_to_supng  (num_suppyrRS_to_supng  ,  
     &                           num_supng  ), 
     & map_suppyrRS_to_supaxax(num_suppyrRS_to_supaxax, 
     &                           num_supaxax),
     & map_suppyrRS_to_supLTS(num_suppyrRS_to_supLTS,   
     &                           num_supLTS),
     & map_suppyrRS_to_spinstell(num_suppyrRS_to_spinstell,
     &                           num_spinstell),
     & map_suppyrRS_to_tuftIB(num_suppyrRS_to_tuftIB,
     &                           num_tuftIB),  
     & map_suppyrRS_to_tuftRS(num_suppyrRS_to_tuftRS,
     &                           num_tuftRS), 
     & map_suppyrRS_to_deepbask(num_suppyrRS_to_deepbask,
     &                           num_deepbask), 
     & map_suppyrRS_to_deepaxax(num_suppyrRS_to_deepaxax,
     &                           num_deepaxax), 
     & map_suppyrRS_to_deepLTS(num_suppyrRS_to_deepLTS,
     &                           num_deepLTS), 
     & map_suppyrRS_to_nontuftrS(num_suppyrRS_to_nontuftRS,
     &                           num_nontuftRS), 
     & map_suppyrFRB_to_suppyrRS(num_suppyrFRB_to_suppyrRS,
     &                           num_suppyrRS) 
              INTEGER
     & map_suppyrFRB_to_suppyrFRB(num_suppyrFRB_to_suppyrFRB,
     &                           num_suppyrFRB),
     & map_suppyrFRB_to_supbask(num_suppyrFRB_to_supbask,
     &                           num_supbask), 
     & map_suppyrFRB_to_supng  (num_suppyrFRB_to_supng  ,
     &                           num_supng  ), 
     & map_suppyrFRB_to_supaxax(num_suppyrFRB_to_supaxax,
     &                           num_supaxax),
     & map_suppyrFRB_to_supLTS(num_suppyrFRB_to_supLTS,
     &                           num_supLTS),
     & map_suppyrFRB_to_spinstell(num_suppyrFRB_to_spinstell,
     &                           num_spinstell),
     & map_suppyrFRB_to_tuftIB(num_suppyrFRB_to_tuftIB,
     &                           num_tuftIB),  
     & map_suppyrFRB_to_tuftRS(num_suppyrFRB_to_tuftRS,
     &                           num_tuftRS),  
     & map_suppyrFRB_to_deepbask(num_suppyrFRB_to_deepbask,
     &                           num_deepbask),
     & map_suppyrFRB_to_deepaxax(num_suppyrFRB_to_deepaxax,
     &                           num_deepaxax),
     & map_suppyrFRB_to_deepLTS(num_suppyrFRB_to_deepLTS,
     &                           num_deepLTS), 
     & map_suppyrFRB_to_nontuftRS(num_suppyrFRB_to_nontuftRS,
     &                           num_nontuftRS),

     & map_supbask_to_suppyrRS(num_supbask_to_suppyrRS,
     &                           num_suppyrRS),  
     & map_supbask_to_suppyrFRB(num_supbask_to_suppyrFRB,
     &                           num_suppyrFRB),
     & map_supbask_to_supbask(num_supbask_to_supbask,
     &                           num_supbask), 
     & map_supbask_to_supng  (num_supbask_to_supng  ,
     &                           num_supng  ),  
     & map_supbask_to_supaxax(num_supbask_to_supaxax,
     &                           num_supaxax),
     & map_supbask_to_supLTS(num_supbask_to_supLTS,
     &                           num_supLTS),  
     & map_supbask_to_spinstell(num_supbask_to_spinstell,
     &                           num_spinstell)  
              INTEGER
     & map_supng_to_suppyrRS  (num_supng_to_suppyrRS ,
     &                           num_suppyrRS),
     & map_supng_to_suppyrFRB (num_supng_to_suppyrFRB,
     &                           num_suppyrFRB),
     & map_supng_to_nontuftRS (num_supng_to_nontuftRS,
     &                           num_nontuftRS),
     & map_supng_to_tuftIB    (num_supng_to_tuftIB   ,
     &                           num_tuftIB   ),
     & map_supng_to_tuftRS    (num_supng_to_tuftRS   ,
     &                           num_tuftRS   ),
     & map_supng_to_supng     (num_supng_to_supng    ,
     &                           num_supng    ),
     & map_supng_to_supbask   (num_supng_to_supbask  ,
     &                           num_supbask  ), 

     & map_supaxax_to_suppyrRS(num_supaxax_to_suppyrRS,
     &                           num_suppyrRS), 
     & map_supaxax_to_suppyrFRB(num_supaxax_to_suppyrFRB,
     &                           num_suppyrFRB), 
     & map_supaxax_to_spinstell(num_supaxax_to_spinstell,
     &                           num_spinstell),
     & map_supaxax_to_tuftIB(num_supaxax_to_tuftIB,
     &                           num_tuftIB),  
     & map_supaxax_to_tuftRS(num_supaxax_to_tuftRS,
     &                           num_tuftRS), 
     & map_supaxax_to_nontuftRS(num_supaxax_to_nontuftRS,
     &                           num_nontuftRS), 
     & map_supLTS_to_suppyrRS(num_supLTS_to_suppyrRS,
     &                           num_suppyrRS),  
     & map_supLTS_to_suppyrFRB(num_supLTS_to_suppyrFRB,
     &                           num_suppyrFRB), 
     & map_supLTS_to_supbask(num_supLTS_to_supbask,
     &                           num_supbask),  
     & map_supLTS_to_supaxax(num_supLTS_to_supaxax,
     &                           num_supaxax), 
     & map_supLTS_to_supLTS(num_supLTS_to_supLTS,
     &                           num_supLTS), 
     & map_supLTS_to_spinstell(num_supLTS_to_spinstell,
     &                           num_spinstell), 
     & map_supLTS_to_tuftIB(num_supLTS_to_tuftIB,
     &                           num_tuftIB),   
     & map_supLTS_to_tuftRS(num_supLTS_to_tuftRS,
     &                           num_tuftRS),  
     & map_supLTS_to_deepbask(num_supLTS_to_deepbask,
     &                           num_deepbask), 
     & map_supLTS_to_deepaxax(num_supLTS_to_deepaxax,
     &                           num_deepaxax), 
     & map_supLTS_to_deepLTS(num_supLTS_to_deepLTS,
     &                           num_deepLTS), 
     & map_supLTS_to_nontuftRS(num_supLTS_to_nontuftRS,
     &                           num_nontuftRS), 
     & map_spinstell_to_suppyrRS(num_spinstell_to_suppyrRS,
     &                           num_suppyrRS),
     & map_spinstell_to_suppyrFRB(num_spinstell_to_suppyrFRB,
     &                           num_suppyrFRB),
     & map_spinstell_to_supbask(num_spinstell_to_supbask,
     &                           num_supbask) 
               INTEGER
     & map_spinstell_to_supaxax(num_spinstell_to_supaxax,
     &                           num_supaxax),
     & map_spinstell_to_supLTS(num_spinstell_to_supLTS,
     &                           num_supLTS), 
     & map_spinstell_to_spinstell(num_spinstell_to_spinstell,
     &                           num_spinstell),
     & map_spinstell_to_tuftIB(num_spinstell_to_tuftIB,
     &                           num_tuftIB),  
     & map_spinstell_to_tuftRS(num_spinstell_to_tuftRS,
     &                           num_tuftRS), 
     & map_spinstell_to_deepbask(num_spinstell_to_deepbask,
     &                           num_deepbask), 
     & map_spinstell_to_deepng  (num_spinstell_to_deepng  ,
     &                           num_deepng  ), 
     & map_spinstell_to_deepaxax(num_spinstell_to_deepaxax,
     &                           num_deepaxax),
     & map_spinstell_to_deepLTS(num_spinstell_to_deepLTS,
     &                           num_deepLTS),
     & map_spinstell_to_nontuftRS(num_spinstell_to_nontuftRS,
     &                           num_nontuftRS),

     & map_tuftIB_to_suppyrRS(num_tuftIB_to_suppyrRS,
     &                           num_suppyrRS),   
     & map_tuftIB_to_suppyrFRB(num_tuftIB_to_suppyrFRB,
     &                           num_suppyrFRB), 
     & map_tuftIB_to_supbask(num_tuftIB_to_supbask,
     &                           num_supbask),  
     & map_tuftIB_to_supaxax(num_tuftIB_to_supaxax,
     &                           num_supaxax), 
     & map_tuftIB_to_supLTS(num_tuftIB_to_supLTS,
     &                           num_supLTS), 
     & map_tuftIB_to_spinstell(num_tuftIB_to_spinstell,
     &                           num_spinstell), 
     & map_tuftIB_to_tuftIB(num_tuftIB_to_tuftIB,
     &                           num_tuftIB),   
     & map_tuftIB_to_tuftRS(num_tuftIB_to_tuftRS,
     &                           num_tuftRS),  
     & map_tuftIB_to_deepbask(num_tuftIB_to_deepbask,
     &                           num_deepbask), 
     & map_tuftIB_to_deepng  (num_tuftIB_to_deepng  ,
     &                           num_deepng  ), 
     & map_tuftIB_to_deepaxax(num_tuftIB_to_deepaxax,
     &                           num_deepaxax),  
     & map_tuftIB_to_deepLTS(num_tuftIB_to_deepLTS,
     &                           num_deepLTS),  
     & map_tuftIB_to_nontuftRS(num_tuftIB_to_nontuftRS,
     &                           num_nontuftRS), 
     & map_tuftRS_to_suppyrRS(num_tuftRS_to_suppyrRS,
     &                           num_suppyrRS), 
     & map_tuftRS_to_suppyrFRB(num_tuftRS_to_suppyrFRB,
     &                           num_suppyrFRB), 
     & map_tuftRS_to_supbask(num_tuftRS_to_supbask,
     &                           num_supbask),  
     & map_tuftRS_to_supaxax(num_tuftRS_to_supaxax,
     &                           num_supaxax),   
     & map_tuftRS_to_supLTS(num_tuftRS_to_supLTS,
     &                           num_supLTS)     
            INTEGER
     & map_tuftRS_to_spinstell(num_tuftRS_to_spinstell,
     &                           num_spinstell), 
     & map_tuftRS_to_tuftIB(num_tuftRS_to_tuftIB,
     &                           num_tuftIB),   
     & map_tuftRS_to_tuftRS(num_tuftRS_to_tuftRS,
     &                           num_tuftRS),     
     & map_tuftRS_to_deepbask(num_tuftRS_to_deepbask,
     &                           num_deepbask),  
     & map_tuftRS_to_deepng  (num_tuftRS_to_deepng  ,
     &                           num_deepng  ),  
     & map_tuftRS_to_deepaxax(num_tuftRS_to_deepaxax,
     &                           num_deepaxax),   
     & map_tuftRS_to_deepLTS(num_tuftRS_to_deepLTS,
     &                           num_deepLTS),   
     & map_tuftRS_to_nontuftRS(num_tuftRS_to_nontuftRS,
     &                           num_nontuftRS),  
     & map_deepbask_to_spinstell(num_deepbask_to_spinstell,
     &                           num_spinstell), 
     & map_deepbask_to_tuftIB(num_deepbask_to_tuftIB,
     &                           num_tuftIB),   
     & map_deepbask_to_tuftRS(num_deepbask_to_tuftRS,
     &                           num_tuftRS),  
     & map_deepbask_to_deepbask(num_deepbask_to_deepbask,
     &                           num_deepbask), 
     & map_deepbask_to_deepng  (num_deepbask_to_deepng  ,
     &                           num_deepng  ), 
     & map_deepbask_to_deepaxax(num_deepbask_to_deepaxax,
     &                           num_deepaxax),  
     & map_deepbask_to_deepLTS(num_deepbask_to_deepLTS,
     &                           num_deepLTS)  
                INTEGER
     & map_deepbask_to_nontuftRS(num_deepbask_to_nontuftRS,
     &                           num_nontuftRS), 
     & map_deepng_to_tuftIB     (num_deepng_to_tuftIB     ,
     &                           num_tuftIB      ),
     & map_deepng_to_tuftRS     (num_deepng_to_tuftRS     ,
     &                           num_tuftRS      ),
     & map_deepng_to_nontuftRS  (num_deepng_to_nontuftRS  ,
     &                           num_nontuftRS   ),
     & map_deepng_to_spinstell  (num_deepng_to_spinstell  ,
     &                           num_spinstell   ),
     & map_deepng_to_deepng     (num_deepng_to_deepng     ,
     &                           num_deepng      ),
     & map_deepng_to_deepbask   (num_deepng_to_deepbask   ,
     &                           num_deepbask    ) 

                INTEGER
     & map_deepaxax_to_suppyrRS(num_deepaxax_to_suppyrRS,
     &                           num_suppyrRS), 
     & map_deepaxax_to_suppyrFRB(num_deepaxax_to_suppyrFRB,
     &                           num_suppyrFRB), 
     & map_deepaxax_to_spinstell(num_deepaxax_to_spinstell,
     &                           num_spinstell),
     & map_deepaxax_to_tuftIB(num_deepaxax_to_tuftIB,
     &                           num_tuftIB), 
     & map_deepaxax_to_tuftRS(num_deepaxax_to_tuftRS,
     &                           num_tuftRS),    
     & map_deepaxax_to_nontuftRS(num_deepaxax_to_nontuftRS,
     &                           num_nontuftRS),
     & map_deepLTS_to_suppyrRS(num_deepLTS_to_suppyrRS,
     &                           num_suppyrRS), 
     & map_deepLTS_to_suppyrFRB(num_deepLTS_to_suppyrFRB,
     &                           num_suppyrFRB), 
     & map_deepLTS_to_supbask(num_deepLTS_to_supbask,
     &                           num_supbask),  
     & map_deepLTS_to_supaxax(num_deepLTS_to_supaxax,
     &                           num_supaxax), 
     & map_deepLTS_to_supLTS(num_deepLTS_to_supLTS,
     &                           num_supLTS), 
     & map_deepLTS_to_spinstell(num_deepLTS_to_spinstell,
     &                           num_spinstell),
     & map_deepLTS_to_tuftIB(num_deepLTS_to_tuftIB,
     &                           num_tuftIB),  
     & map_deepLTS_to_tuftRS(num_deepLTS_to_tuftRS,
     &                            num_tuftRS), 
     & map_deepLTS_to_deepbask(num_deepLTS_to_deepbask,
     &                            num_deepbask), 
     & map_deepLTS_to_deepaxax(num_deepLTS_to_deepaxax,
     &                            num_deepaxax),  
     & map_deepLTS_to_deepLTS(num_deepLTS_to_deepLTS,
     &                            num_deepLTS),  
     & map_deepLTS_to_nontuftRS(num_deepLTS_to_nontuftRS,
     &                            num_nontuftRS), 
     & map_TCR_to_suppyrRS(num_TCR_to_suppyrRS,
     &                            num_suppyrRS),     
     & map_TCR_to_suppyrFRB(num_TCR_to_suppyrFRB,
     &                            num_suppyrFRB),   
     & map_TCR_to_supbask(num_TCR_to_supbask,
     &                            num_supbask)    
               INTEGER
     & map_TCR_to_supng  (num_TCR_to_supng  ,
     &                            num_supng  ),   
     & map_TCR_to_supaxax(num_TCR_to_supaxax,num_supaxax),   
     & map_TCR_to_spinstell(num_TCR_to_spinstell,num_spinstell),
     & map_TCR_to_tuftIB(num_TCR_to_tuftIB,num_tuftIB),  
     & map_TCR_to_tuftRS(num_TCR_to_tuftRS,num_tuftRS),    
     & map_TCR_to_deepbask(num_TCR_to_deepbask,num_deepbask), 
     & map_TCR_to_deepng  (num_TCR_to_deepng  ,num_deepng  ), 
     & map_TCR_to_deepaxax(num_TCR_to_deepaxax,num_deepaxax),
     & map_TCR_to_nRT(num_TCR_to_nRT,num_nRT),    
     & map_TCR_to_nontuftRS(num_TCR_to_nontuftRS,num_nontuftRS), 
     & map_nRT_to_TCR(num_nRT_to_TCR,num_TCR),      
     & map_nRT_to_nRT(num_nRT_to_nRT,num_nRT),     
     & map_nontuftRS_to_suppyrRS(num_nontuftRS_to_suppyrRS,
     &                             num_suppyrRS), 
     & map_nontuftRS_to_suppyrFRB(num_nontuftRS_to_suppyrFRB,
     &                             num_suppyrFRB),
     & map_nontuftRS_to_supbask(num_nontuftRS_to_supbask,
     &                             num_supbask), 
     & map_nontuftRS_to_supaxax(num_nontuftRS_to_supaxax,
     &                             num_supaxax),
     & map_nontuftRS_to_supLTS(num_nontuftRS_to_supLTS,
     &                             num_supLTS),  
     & map_nontuftRS_to_spinstell(num_nontuftRS_to_spinstell,
     &                             num_spinstell),
     & map_nontuftRS_to_tuftIB(num_nontuftRS_to_tuftIB,
     &                             num_tuftIB),  
     & map_nontuftRS_to_tuftRS(num_nontuftRS_to_tuftRS,
     &                             num_tuftRS),  
     & map_nontuftRS_to_deepbask(num_nontuftRS_to_deepbask,
     &                             num_deepbask), 
     & map_nontuftRS_to_deepng  (num_nontuftRS_to_deepng  ,
     &                             num_deepng  ), 
     & map_nontuftRS_to_deepaxax(num_nontuftRS_to_deepaxax,
     &                             num_deepaxax),
     & map_nontuftRS_to_deepLTS(num_nontuftRS_to_deepLTS,
     &                             num_deepLTS),
     & map_nontuftRS_to_TCR(num_nontuftRS_to_TCR,num_TCR),
     & map_nontuftRS_to_nRT(num_nontuftRS_to_nRT,num_nRT),  
     & map_nontuftRS_to_nontuftRS(num_nontuftRS_to_nontuftRS,
     &                             num_nontuftRS)

c Maps of synaptic compartments.  For simplicity, all contacts
c only made to one compartment.  Axoaxonic cells forced to contact 
c initial axon segments; other compartments will be listed in arrays.
        INTEGER 
     & com_suppyrRS_to_suppyrRS(num_suppyrRS_to_suppyrRS,
     &                           num_suppyrRS),
     & com_suppyrRS_to_suppyrFRB(num_suppyrRS_to_suppyrFRB,
     &                           num_suppyrFRB),
     & com_suppyrRS_to_supbask(num_suppyrRS_to_supbask,  
     &                           num_supbask), 
     & com_suppyrRS_to_supng  (num_suppyrRS_to_supng  ,  
     &                           num_supng  ), 
     & com_suppyrRS_to_supaxax(num_suppyrRS_to_supaxax, 
     &                           num_supaxax),
     & com_suppyrRS_to_supLTS(num_suppyrRS_to_supLTS,   
     &                           num_supLTS),
     & com_suppyrRS_to_spinstell(num_suppyrRS_to_spinstell,
     &                           num_spinstell),
     & com_suppyrRS_to_tuftIB(num_suppyrRS_to_tuftIB,
     &                           num_tuftIB),  
     & com_suppyrRS_to_tuftRS(num_suppyrRS_to_tuftRS,
     &                           num_tuftRS), 
     & com_suppyrRS_to_deepbask(num_suppyrRS_to_deepbask,
     &                           num_deepbask), 
     & com_suppyrRS_to_deepaxax(num_suppyrRS_to_deepaxax,
     &                           num_deepaxax), 
     & com_suppyrRS_to_deepLTS(num_suppyrRS_to_deepLTS,
     &                           num_deepLTS), 
     & com_suppyrRS_to_nontuftrS(num_suppyrRS_to_nontuftRS,
     &                           num_nontuftRS), 
     & com_suppyrFRB_to_suppyrRS(num_suppyrFRB_to_suppyrRS,
     &                           num_suppyrRS) 
              INTEGER
     & com_suppyrFRB_to_suppyrFRB(num_suppyrFRB_to_suppyrFRB,
     &                           num_suppyrFRB),
     & com_suppyrFRB_to_supbask(num_suppyrFRB_to_supbask,
     &                           num_supbask), 
     & com_suppyrFRB_to_supng  (num_suppyrFRB_to_supng  ,
     &                           num_supng  ), 
     & com_suppyrFRB_to_supaxax(num_suppyrFRB_to_supaxax,
     &                           num_supaxax),
     & com_suppyrFRB_to_supLTS(num_suppyrFRB_to_supLTS,
     &                           num_supLTS),
     & com_suppyrFRB_to_spinstell(num_suppyrFRB_to_spinstell,
     &                           num_spinstell),
     & com_suppyrFRB_to_tuftIB(num_suppyrFRB_to_tuftIB,
     &                           num_tuftIB),  
     & com_suppyrFRB_to_tuftRS(num_suppyrFRB_to_tuftRS,
     &                           num_tuftRS),  
     & com_suppyrFRB_to_deepbask(num_suppyrFRB_to_deepbask,
     &                           num_deepbask),
     & com_suppyrFRB_to_deepaxax(num_suppyrFRB_to_deepaxax,
     &                           num_deepaxax),
     & com_suppyrFRB_to_deepLTS(num_suppyrFRB_to_deepLTS,
     &                           num_deepLTS), 
     & com_suppyrFRB_to_nontuftRS(num_suppyrFRB_to_nontuftRS,
     &                           num_nontuftRS),
     & com_supbask_to_suppyrRS(num_supbask_to_suppyrRS,
     &                           num_suppyrRS),  
     & com_supbask_to_suppyrFRB(num_supbask_to_suppyrFRB,
     &                           num_suppyrFRB),
     & com_supbask_to_supbask(num_supbask_to_supbask,
     &                           num_supbask), 
     & com_supbask_to_supng  (num_supbask_to_supng  ,
     &                           num_supng  ), 
     & com_supbask_to_supaxax(num_supbask_to_supaxax,
     &                           num_supaxax),
     & com_supbask_to_supLTS(num_supbask_to_supLTS,
     &                           num_supLTS),  
     & com_supbask_to_spinstell(num_supbask_to_spinstell,
     &                           num_spinstell)  

          INTEGER
     & com_supng_to_suppyrRS  (num_supng_to_suppyrRS,
     &                         num_suppyrRS),
     & com_supng_to_suppyrFRB (num_supng_to_suppyrFRB,
     &                         num_suppyrFRB),
     & com_supng_to_nontuftRS (num_supng_to_nontuftRS,
     &                         num_nontuftRS),
     & com_supng_to_tuftIB    (num_supng_to_tuftIB   ,
     &                         num_tuftIB   ),
     & com_supng_to_tuftRS    (num_supng_to_tuftRS   ,
     &                         num_tuftRS   ),
     & com_supng_to_supng     (num_supng_to_supng    ,
     &                         num_supng    ),
     & com_supng_to_supbask   (num_supng_to_supbask  ,
     &                         num_supbask  ) 

          INTEGER
     & com_supaxax_to_suppyrRS(num_supaxax_to_suppyrRS,
     &                           num_suppyrRS), 
     & com_supaxax_to_suppyrFRB(num_supaxax_to_suppyrFRB,
     &                           num_suppyrFRB), 
     & com_supaxax_to_spinstell(num_supaxax_to_spinstell,
     &                           num_spinstell)
           INTEGER
     & com_supaxax_to_tuftIB(num_supaxax_to_tuftIB,
     &                           num_tuftIB),  
     & com_supaxax_to_tuftRS(num_supaxax_to_tuftRS,
     &                           num_tuftRS), 
     & com_supaxax_to_nontuftRS(num_supaxax_to_nontuftRS,
     &                           num_nontuftRS), 
     & com_supLTS_to_suppyrRS(num_supLTS_to_suppyrRS,
     &                           num_suppyrRS),  
     & com_supLTS_to_suppyrFRB(num_supLTS_to_suppyrFRB,
     &                           num_suppyrFRB), 
     & com_supLTS_to_supbask(num_supLTS_to_supbask,
     &                           num_supbask),  
     & com_supLTS_to_supaxax(num_supLTS_to_supaxax,
     &                           num_supaxax), 
     & com_supLTS_to_supLTS(num_supLTS_to_supLTS,
     &                           num_supLTS), 
     & com_supLTS_to_spinstell(num_supLTS_to_spinstell,
     &                           num_spinstell), 
     & com_supLTS_to_tuftIB(num_supLTS_to_tuftIB,
     &                           num_tuftIB),   
     & com_supLTS_to_tuftRS(num_supLTS_to_tuftRS,
     &                           num_tuftRS),  
     & com_supLTS_to_deepbask(num_supLTS_to_deepbask,
     &                           num_deepbask), 
     & com_supLTS_to_deepaxax(num_supLTS_to_deepaxax,
     &                           num_deepaxax), 
     & com_supLTS_to_deepLTS(num_supLTS_to_deepLTS,
     &                           num_deepLTS), 
     & com_supLTS_to_nontuftRS(num_supLTS_to_nontuftRS,
     &                           num_nontuftRS), 
     & com_spinstell_to_suppyrRS(num_spinstell_to_suppyrRS,
     &                           num_suppyrRS),
     & com_spinstell_to_suppyrFRB(num_spinstell_to_suppyrFRB,
     &                           num_suppyrFRB),
     & com_spinstell_to_supbask(num_spinstell_to_supbask,
     &                           num_supbask), 
     & com_spinstell_to_supaxax(num_spinstell_to_supaxax,
     &                           num_supaxax)
                INTEGER
     & com_spinstell_to_supLTS(num_spinstell_to_supLTS,
     &                           num_supLTS), 
     & com_spinstell_to_spinstell(num_spinstell_to_spinstell,
     &                           num_spinstell),
     & com_spinstell_to_tuftIB(num_spinstell_to_tuftIB,
     &                           num_tuftIB),  
     & com_spinstell_to_tuftRS(num_spinstell_to_tuftRS,
     &                           num_tuftRS), 
     & com_spinstell_to_deepbask(num_spinstell_to_deepbask,
     &                           num_deepbask), 
     & com_spinstell_to_deepng  (num_spinstell_to_deepng  ,
     &                           num_deepng  ), 
     & com_spinstell_to_deepaxax(num_spinstell_to_deepaxax,
     &                           num_deepaxax),
     & com_spinstell_to_deepLTS(num_spinstell_to_deepLTS,
     &                           num_deepLTS),
     & com_spinstell_to_nontuftRS(num_spinstell_to_nontuftRS,
     &                           num_nontuftRS),
     & com_tuftIB_to_suppyrRS(num_tuftIB_to_suppyrRS,
     &                           num_suppyrRS),   
     & com_tuftIB_to_suppyrFRB(num_tuftIB_to_suppyrFRB,
     &                           num_suppyrFRB), 
     & com_tuftIB_to_supbask(num_tuftIB_to_supbask,
     &                           num_supbask),  
     & com_tuftIB_to_supaxax(num_tuftIB_to_supaxax,
     &                           num_supaxax), 
     & com_tuftIB_to_supLTS(num_tuftIB_to_supLTS,
     &                           num_supLTS), 
     & com_tuftIB_to_spinstell(num_tuftIB_to_spinstell,
     &                           num_spinstell), 
     & com_tuftIB_to_tuftIB(num_tuftIB_to_tuftIB,
     &                           num_tuftIB),   
     & com_tuftIB_to_tuftRS(num_tuftIB_to_tuftRS,
     &                           num_tuftRS),  
     & com_tuftIB_to_deepbask(num_tuftIB_to_deepbask,
     &                           num_deepbask), 
     & com_tuftIB_to_deepng  (num_tuftIB_to_deepng  ,
     &                           num_deepng  ), 
     & com_tuftIB_to_deepaxax(num_tuftIB_to_deepaxax,
     &                           num_deepaxax),  
     & com_tuftIB_to_deepLTS(num_tuftIB_to_deepLTS,
     &                           num_deepLTS),  
     & com_tuftIB_to_nontuftRS(num_tuftIB_to_nontuftRS,
     &                           num_nontuftRS) 
              INTEGER
     & com_tuftRS_to_suppyrRS(num_tuftRS_to_suppyrRS,
     &                           num_suppyrRS), 
     & com_tuftRS_to_suppyrFRB(num_tuftRS_to_suppyrFRB,
     &                           num_suppyrFRB), 
     & com_tuftRS_to_supbask(num_tuftRS_to_supbask,
     &                           num_supbask),  
     & com_tuftRS_to_supaxax(num_tuftRS_to_supaxax,
     &                           num_supaxax),   
     & com_tuftRS_to_supLTS(num_tuftRS_to_supLTS,
     &                           num_supLTS),     
     & com_tuftRS_to_spinstell(num_tuftRS_to_spinstell,
     &                           num_spinstell), 
     & com_tuftRS_to_tuftIB(num_tuftRS_to_tuftIB,
     &                           num_tuftIB),   
     & com_tuftRS_to_tuftRS(num_tuftRS_to_tuftRS,
     &                           num_tuftRS),     
     & com_tuftRS_to_deepbask(num_tuftRS_to_deepbask,
     &                           num_deepbask),  
     & com_tuftRS_to_deepng  (num_tuftRS_to_deepng  ,
     &                           num_deepng  ),  
     & com_tuftRS_to_deepaxax(num_tuftRS_to_deepaxax,
     &                           num_deepaxax),   
     & com_tuftRS_to_deepLTS(num_tuftRS_to_deepLTS,
     &                           num_deepLTS),   
     & com_tuftRS_to_nontuftRS(num_tuftRS_to_nontuftRS,
     &                           num_nontuftRS),  
     & com_deepbask_to_spinstell(num_deepbask_to_spinstell,
     &                           num_spinstell), 
     & com_deepbask_to_tuftIB(num_deepbask_to_tuftIB,
     &                           num_tuftIB),   
     & com_deepbask_to_tuftRS(num_deepbask_to_tuftRS,
     &                           num_tuftRS),  
     & com_deepbask_to_deepbask(num_deepbask_to_deepbask,
     &                           num_deepbask), 
     & com_deepbask_to_deepng  (num_deepbask_to_deepng  ,
     &                           num_deepng  ), 
     & com_deepbask_to_deepaxax(num_deepbask_to_deepaxax,
     &                           num_deepaxax),  
     & com_deepbask_to_deepLTS(num_deepbask_to_deepLTS,
     &                           num_deepLTS),  
     & com_deepbask_to_nontuftRS(num_deepbask_to_nontuftRS,
     &                           num_nontuftRS) 
            INTEGER
     & com_deepng_to_tuftIB     (num_deepng_to_tuftIB    ,
     &                           num_tuftIB      ),
     & com_deepng_to_tuftRS     (num_deepng_to_tuftRS    ,
     &                           num_tuftRS      ),
     & com_deepng_to_nontuftRS  (num_deepng_to_nontuftRS ,
     &                           num_nontuftRS   ),
     & com_deepng_to_spinstell  (num_deepng_to_spinstell ,
     &                           num_spinstell   ),
     & com_deepng_to_deepng     (num_deepng_to_deepng    ,
     &                           num_deepng      ),
     & com_deepng_to_deepbask   (num_deepng_to_deepbask  ,
     &                           num_deepbask    ) 
            INTEGER
     & com_deepaxax_to_suppyrRS(num_deepaxax_to_suppyrRS,
     &                           num_suppyrRS), 
     & com_deepaxax_to_suppyrFRB(num_deepaxax_to_suppyrFRB,
     &                           num_suppyrFRB), 
     & com_deepaxax_to_spinstell(num_deepaxax_to_spinstell,
     &                           num_spinstell),
     & com_deepaxax_to_tuftIB(num_deepaxax_to_tuftIB,
     &                           num_tuftIB), 
     & com_deepaxax_to_tuftRS(num_deepaxax_to_tuftRS,
     &                           num_tuftRS),    
     & com_deepaxax_to_nontuftRS(num_deepaxax_to_nontuftRS,
     &                           num_nontuftRS),
     & com_deepLTS_to_suppyrRS(num_deepLTS_to_suppyrRS,
     &                           num_suppyrRS), 
     & com_deepLTS_to_suppyrFRB(num_deepLTS_to_suppyrFRB,
     &                           num_suppyrFRB), 
     & com_deepLTS_to_supbask(num_deepLTS_to_supbask,
     &                           num_supbask),  
     & com_deepLTS_to_supaxax(num_deepLTS_to_supaxax,
     &                           num_supaxax), 
     & com_deepLTS_to_supLTS(num_deepLTS_to_supLTS,
     &                           num_supLTS), 
     & com_deepLTS_to_spinstell(num_deepLTS_to_spinstell,
     &                           num_spinstell),
     & com_deepLTS_to_tuftIB(num_deepLTS_to_tuftIB,
     &                           num_tuftIB),  
     & com_deepLTS_to_tuftRS(num_deepLTS_to_tuftRS,
     &                            num_tuftRS), 
     & com_deepLTS_to_deepbask(num_deepLTS_to_deepbask,
     &                            num_deepbask), 
     & com_deepLTS_to_deepaxax(num_deepLTS_to_deepaxax,
     &                            num_deepaxax),  
     & com_deepLTS_to_deepLTS(num_deepLTS_to_deepLTS,
     &                            num_deepLTS)  
           INTEGER
     & com_deepLTS_to_nontuftRS(num_deepLTS_to_nontuftRS,
     &                            num_nontuftRS), 
     & com_TCR_to_suppyrRS(num_TCR_to_suppyrRS,
     &                            num_suppyrRS),     
     & com_TCR_to_suppyrFRB(num_TCR_to_suppyrFRB,
     &                            num_suppyrFRB),   
     & com_TCR_to_supbask(num_TCR_to_supbask,
     &                            num_supbask),    
     & com_TCR_to_supng  (num_TCR_to_supng  ,
     &                            num_supng  ),    
     & com_TCR_to_supaxax(num_TCR_to_supaxax,num_supaxax),   
     & com_TCR_to_spinstell(num_TCR_to_spinstell,num_spinstell),
     & com_TCR_to_tuftIB(num_TCR_to_tuftIB,num_tuftIB),  
     & com_TCR_to_tuftRS(num_TCR_to_tuftRS,num_tuftRS),    
     & com_TCR_to_deepbask(num_TCR_to_deepbask,num_deepbask), 
     & com_TCR_to_deepng  (num_TCR_to_deepng  ,num_deepng  ), 
     & com_TCR_to_deepaxax(num_TCR_to_deepaxax,num_deepaxax),
     & com_TCR_to_nRT(num_TCR_to_nRT,num_nRT),    
     & com_TCR_to_nontuftRS(num_TCR_to_nontuftRS,num_nontuftRS), 
     & com_nRT_to_TCR(num_nRT_to_TCR,num_TCR),      
     & com_nRT_to_nRT(num_nRT_to_nRT,num_nRT),     
     & com_nontuftRS_to_suppyrRS(num_nontuftRS_to_suppyrRS,
     &                             num_suppyrRS), 
     & com_nontuftRS_to_suppyrFRB(num_nontuftRS_to_suppyrFRB,
     &                             num_suppyrFRB),
     & com_nontuftRS_to_supbask(num_nontuftRS_to_supbask,
     &                             num_supbask), 
     & com_nontuftRS_to_supaxax(num_nontuftRS_to_supaxax,
     &                             num_supaxax),
     & com_nontuftRS_to_supLTS(num_nontuftRS_to_supLTS,
     &                             num_supLTS),  
     & com_nontuftRS_to_spinstell(num_nontuftRS_to_spinstell,
     &                             num_spinstell),
     & com_nontuftRS_to_tuftIB(num_nontuftRS_to_tuftIB,
     &                             num_tuftIB)  
              INTEGER
     & com_nontuftRS_to_tuftRS(num_nontuftRS_to_tuftRS,
     &                             num_tuftRS),  
     & com_nontuftRS_to_deepbask(num_nontuftRS_to_deepbask,
     &                             num_deepbask), 
     & com_nontuftRS_to_deepng  (num_nontuftRS_to_deepng  ,
     &                             num_deepng  ), 
     & com_nontuftRS_to_deepaxax(num_nontuftRS_to_deepaxax,
     &                             num_deepaxax),
     & com_nontuftRS_to_deepLTS(num_nontuftRS_to_deepLTS,
     &                             num_deepLTS),
     & com_nontuftRS_to_TCR(num_nontuftRS_to_TCR,num_TCR),
     & com_nontuftRS_to_nRT(num_nontuftRS_to_nRT,num_nRT),  
     & com_nontuftRS_to_nontuftRS(num_nontuftRS_to_nontuftRS,
     &                             num_nontuftRS)

c Entries in gjtable are cell a, compart. of cell a with gj,
c  cell b, compart. of cell b with gj; entries not repeated,
c which means that, for given cell being integrated, table
c must be searched through cols. 1 and 3.
       integer gjtable_suppyrRS(totaxgj_suppyrRS,4),
     &   gjtable_suppyrFRB(totaxgj_suppyrFRB,4),
     &   gjtable_suppyr   (totaxgj_suppyr,4),
! gjtable_suppyr for suppyrRS/suppyrFRB gj, with RS cell
! in col. 1 and FRB cell in col. 3
     &   gjtable_supbask  (totSDgj_supbask,4),
     &   gjtable_supng    (totSDgj_supng  ,4),
     &   gjtable_supaxax  (1              ,4),
     &   gjtable_supLTS   (totSDgj_supLTS,4),
     &   gjtable_spinstell(totaxgj_spinstell,4),
     &   gjtable_tuftIB   (totaxgj_tuftIB,4),
     &   gjtable_tuftRS   (totaxgj_tuftRS,4),
     &   gjtable_tuft     (totaxgj_tuft,4),
! gjtable_tuft for tuftIB/tuftRS gj, with IB cell
! in col. 1 and RS cell in col. 3.
     &   gjtable_nontuftRS(totaxgj_nontuftRS,4),
     &   gjtable_deepbask (totSDgj_deepbask,4),
     &   gjtable_deepng   (totSDgj_deepng  ,4),
     &   gjtable_deepaxax (1               ,4),
     &   gjtable_deepLTS  (totSDgj_deepLTS,4),
     &   gjtable_TCR      (totaxgj_TCR,4),
     &   gjtable_nRT      (totSDgj_nRT,4) 

c define compartments on which gj can form
       INTEGER
     &table_axgjcompallow_suppyrRS(num_axgjcompallow_suppyrRS)
     &          /74/,
c    &          /73/, ! 28 Nov. 2005, move proximally, to get more inhib. control.
     &table_axgjcompallow_suppyrFRB(num_axgjcompallow_suppyrFRB)
     &          /74/,
c    &          /73/, ! 28 Nov. 2005, move proximally
c Ectopics to superficial pyr. cells then go to #72, see
c   supergj.f
     &table_SDgjcompallow_supbask  (num_SDgjcompallow_supbask  )
     &          /3,4,16,17,29,30,42,43/,
     &table_SDgjcompallow_supng    (num_SDgjcompallow_supng    )
     &          /3,4,16,17,29,30,42,43/,
     &table_SDgjcompallow_supLTS   (num_SDgjcompallow_supLTS   )
     &          /3,4,16,17,29,30,42,43/,
     &table_axgjcompallow_spinstell(num_axgjcompallow_spinstell)
     &          /59/,
c Ectopics to spiny stellates then go to #57
     &table_axgjcompallow_tuftIB   (num_axgjcompallow_tuftIB   )
     &          /61/,
     &table_axgjcompallow_tuftRS   (num_axgjcompallow_tuftRS   )
     &          /61/,
c Ectopics to tufted pyr. cells then go to #60
     &table_axgjcompallow_nontuftRS(num_axgjcompallow_nontuftRS)
     &          /50/,
c Ectopics to nontufted deep pyr. cells then to #48
     &table_SDgjcompallow_deepbask (num_SDgjcompallow_deepbask )
     &          /3,4,16,17,29,30,42,43/,
     &table_SDgjcompallow_deepng   (num_SDgjcompallow_deepng   )
     &          /3,4,16,17,29,30,42,43/,
     &table_SDgjcompallow_deepLTS  (num_SDgjcompallow_deepLTS  )
     &          /3,4,16,17,29,30,42,43/,
     &table_axgjcompallow_TCR      (num_axgjcompallow_TCR      )
     &          /137/,
c Ectopics to TCR cells to #135
     &table_SDgjcompallow_nRT      (num_SDgjcompallow_nRT      )
     &          /3,4,16,17,29,30,42,43/

       integer ectr_suppyrRS, ectr_suppyrFRB, ectr_supbask,
     &  ectr_supng, ectr_deepng,
     &  ectr_supaxax, ectr_supLTS, ectr_spinstell,
     &  ectr_tuftIB, ectr_tuftRS, ectr_nontuftRS,
     &  ectr_deepbask, ectr_deepaxax, ectr_deepLTS,
     &  ectr_TCR, ectr_nRT

!      real*8 field_1mm_suppyrRS, field_1mm_suppyrFRB,
!    &  field_1mm_nontuftRS, field_1mm_tuftIB, field_1mm_tuftRS
!      real*8 field_2mm_suppyrRS, field_2mm_suppyrFRB,
!    &  field_2mm_nontuftRS, field_2mm_tuftIB, field_2mm_tuftRS
       real*8 field_1mm, field_2mm ! scalars to pass to subroutines
       real*8 field_1mm_local(1), field_2mm_local(1)  ! for mpi
       real*8 field_1mm_global(numnodes), field_2mm_global(numnodes) ! for mpi
       real*8 field_1mm_tot, field_2mm_tot  ! sums of global vectors

c Define tables used for computing dexp & GABA-B timecourse:
c dexptablesmall(i) = dexp(-z), i = int (z*1000.), 0<=z<=5.
c dexptablebig  (i) = dexp(-z), i = int (z*10.), 0<=z<=100.
        double precision:: dexptablesmall(0:5000)
        double precision::  dexptablebig  (0:1000)
        double precision:: otis_table (0:50000)
! if how_often = 50 and dt = .002, then otis_table structure
! corresponds to time steps of 0.1 ms, and it gives 5 s of data.

        real*8 noisepe_tuftIB  ! noisepe_tuftIB_save defined as parameter above
        real*8 noisepe_tuftRS  ! noisepe_tuftRS_save defined as parameter above

c Define arrays, constants, for voltages, applied currents,
c synaptic conductances, random numbers, etc.

       double precision::
     &  V_suppyrRS  (numcomp_suppyrRS, num_suppyrRS),
     &  V_suppyrFRB (numcomp_suppyrFRB,num_suppyrFRB), 
     &  V_supbask   (numcomp_supbask,  num_supbask),  
     &  V_supng     (numcomp_supng  ,  num_supng  ),  
     &  V_supaxax   (numcomp_supaxax,  num_supaxax), 
     &  V_supLTS    (numcomp_supLTS,   num_supLTS), 
     &  V_spinstell (numcomp_spinstell,num_spinstell),
     &  V_tuftIB    (numcomp_tuftIB,   num_tuftIB),  
     &  V_tuftRS    (numcomp_tuftRS,   num_tuftRS), 
     &  V_nontuftRS (numcomp_nontuftRS,num_nontuftRS),
     &  V_deepbask  (numcomp_deepbask, num_deepbask),
     &  V_deepng    (numcomp_deepng  , num_deepng  ),
     &  V_deepaxax  (numcomp_deepaxax, num_deepaxax),
     &  V_deepLTS   (numcomp_deepLTS,  num_deepLTS),
     &  V_TCR       (numcomp_TCR,      num_TCR),   
     &  V_nRT       (numcomp_nRT,      num_nRT) 

       double precision::
     &  curr_suppyrRS   (numcomp_suppyrRS, num_suppyrRS),
     &  curr_suppyrFRB  (numcomp_suppyrFRB,num_suppyrFRB), 
     &  curr_supbask    (numcomp_supbask,  num_supbask),  
     &  curr_supng      (numcomp_supng  ,  num_supng  ),  
     &  curr_supaxax    (numcomp_supaxax,  num_supaxax), 
     &  curr_supLTS     (numcomp_supLTS,   num_supLTS), 
     &  curr_spinstell  (numcomp_spinstell,num_spinstell),
     &  curr_tuftIB     (numcomp_tuftIB,   num_tuftIB),  
     &  curr_tuftRS     (numcomp_tuftRS,   num_tuftRS), 
     &  curr_nontuftRS  (numcomp_nontuftRS,num_nontuftRS),
     &  curr_deepbask   (numcomp_deepbask, num_deepbask),
     &  curr_deepng     (numcomp_deepng  , num_deepng  ),
     &  curr_deepaxax   (numcomp_deepaxax, num_deepaxax),
     &  curr_deepLTS    (numcomp_deepLTS,  num_deepLTS),
     &  curr_TCR        (numcomp_TCR,      num_TCR),   
     &  curr_nRT        (numcomp_nRT,      num_nRT) 

       double precision::
     & gAMPA_suppyrRS   (numcomp_suppyrRS, num_suppyrRS),
     & gAMPA_suppyrFRB  (numcomp_suppyrFRB,num_suppyrFRB), 
     & gAMPA_supbask    (numcomp_supbask,  num_supbask),  
     & gAMPA_supng      (numcomp_supng  ,  num_supng  ),  
     & gAMPA_supaxax    (numcomp_supaxax,  num_supaxax), 
     & gAMPA_supLTS     (numcomp_supLTS,   num_supLTS), 
     & gAMPA_spinstell  (numcomp_spinstell,num_spinstell),
     & gAMPA_tuftIB     (numcomp_tuftIB,   num_tuftIB),  
     & gAMPA_tuftRS     (numcomp_tuftRS,   num_tuftRS), 
     & gAMPA_nontuftRS  (numcomp_nontuftRS,num_nontuftRS),
     & gAMPA_deepbask   (numcomp_deepbask, num_deepbask),
     & gAMPA_deepng     (numcomp_deepng  , num_deepng  ),
     & gAMPA_deepaxax   (numcomp_deepaxax, num_deepaxax),
     & gAMPA_deepLTS    (numcomp_deepLTS,  num_deepLTS),
     & gAMPA_TCR        (numcomp_TCR,      num_TCR),   
     & gAMPA_nRT        (numcomp_nRT,      num_nRT) 

       double precision::
     & gNMDA_suppyrRS   (numcomp_suppyrRS, num_suppyrRS),
     & gNMDA_suppyrFRB  (numcomp_suppyrFRB,num_suppyrFRB), 
     & gNMDA_supbask    (numcomp_supbask,  num_supbask),  
     & gNMDA_supng      (numcomp_supng  ,  num_supng  ),  
     & gNMDA_supaxax    (numcomp_supaxax,  num_supaxax), 
     & gNMDA_supLTS     (numcomp_supLTS,   num_supLTS), 
     & gNMDA_spinstell  (numcomp_spinstell,num_spinstell),
     & gNMDA_tuftIB     (numcomp_tuftIB,   num_tuftIB),  
     & gNMDA_tuftRS     (numcomp_tuftRS,   num_tuftRS), 
     & gNMDA_nontuftRS  (numcomp_nontuftRS,num_nontuftRS),
     & gNMDA_deepbask   (numcomp_deepbask, num_deepbask),
     & gNMDA_deepng     (numcomp_deepng  , num_deepng  ),
     & gNMDA_deepaxax   (numcomp_deepaxax, num_deepaxax),
     & gNMDA_deepLTS    (numcomp_deepLTS,  num_deepLTS),
     & gNMDA_TCR        (numcomp_TCR,      num_TCR),   
     & gNMDA_nRT        (numcomp_nRT,      num_nRT) 

       double precision::
     & gGABA_A_suppyrRS (numcomp_suppyrRS, num_suppyrRS),
     & gGABA_A_suppyrFRB(numcomp_suppyrFRB,num_suppyrFRB), 
     & gGABA_A_supbask  (numcomp_supbask,  num_supbask),  
     & gGABA_A_supng    (numcomp_supng  ,  num_supng  ),  
     & gGABA_A_supaxax  (numcomp_supaxax,  num_supaxax), 
     & gGABA_A_supLTS   (numcomp_supLTS,   num_supLTS), 
     & gGABA_A_spinstell(numcomp_spinstell,num_spinstell),
     & gGABA_A_tuftIB   (numcomp_tuftIB,   num_tuftIB),  
     & gGABA_A_tuftRS   (numcomp_tuftRS,   num_tuftRS), 
     & gGABA_A_nontuftRS(numcomp_nontuftRS,num_nontuftRS),
     & gGABA_A_deepbask (numcomp_deepbask, num_deepbask),
     & gGABA_A_deepng   (numcomp_deepng  , num_deepng  ),
     & gGABA_A_deepaxax (numcomp_deepaxax, num_deepaxax),
     & gGABA_A_deepLTS  (numcomp_deepLTS,  num_deepLTS),
     & gGABA_A_TCR      (numcomp_TCR,      num_TCR),   
     & gGABA_A_nRT      (numcomp_nRT,      num_nRT) 

       double precision::
     & gGABA_B_suppyrRS (numcomp_suppyrRS, num_suppyrRS),
     & gGABA_B_suppyrFRB(numcomp_suppyrFRB,num_suppyrFRB), 
     & gGABA_B_spinstell(numcomp_spinstell,num_spinstell),
     & gGABA_B_tuftIB   (numcomp_tuftIB,   num_tuftIB),  
     & gGABA_B_tuftRS   (numcomp_tuftRS,   num_tuftRS), 
     & gGABA_B_nontuftRS(numcomp_nontuftRS,num_nontuftRS),
     & gGABA_B_TCR      (numcomp_TCR,      num_TCR),   
     & gGABA_B_nRT      (numcomp_nRT,      num_nRT) 

! define membrane and Ca state variables that must be passed
! to subroutines
       real*8  chi_suppyrRS(numcomp_suppyrRS,num_suppyrRS)
       real*8  mnaf_suppyrRS(numcomp_suppyrRS,num_suppyrRS),
     & mnap_suppyrRS(numcomp_suppyrRS,num_suppyrRS),
     x hnaf_suppyrRS(numcomp_suppyrRS,num_suppyrRS),
     x mkdr_suppyrRS(numcomp_suppyrRS,num_suppyrRS),
     x mka_suppyrRS(numcomp_suppyrRS,num_suppyrRS),
     x hka_suppyrRS(numcomp_suppyrRS,num_suppyrRS),
     x mk2_suppyrRS(numcomp_suppyrRS,num_suppyrRS), 
     x hk2_suppyrRS(numcomp_suppyrRS,num_suppyrRS),
     x mkm_suppyrRS(numcomp_suppyrRS,num_suppyrRS),
     x mkc_suppyrRS(numcomp_suppyrRS,num_suppyrRS),
     x mkahp_suppyrRS(numcomp_suppyrRS,num_suppyrRS),
     x mcat_suppyrRS(numcomp_suppyrRS,num_suppyrRS),
     x hcat_suppyrRS(numcomp_suppyrRS,num_suppyrRS),
     x mcal_suppyrRS(numcomp_suppyrRS,num_suppyrRS),
     x mar_suppyrRS(numcomp_suppyrRS,num_suppyrRS)

       real*8  chi_suppyrFRB(numcomp_suppyrFRB,num_suppyrFRB)
       real*8  mnaf_suppyrFRB(numcomp_suppyrFRB,num_suppyrFRB),
     & mnap_suppyrFRB(numcomp_suppyrFRB,num_suppyrFRB),
     x hnaf_suppyrFRB(numcomp_suppyrFRB,num_suppyrFRB),
     x mkdr_suppyrFRB(numcomp_suppyrFRB,num_suppyrFRB),
     x mka_suppyrFRB(numcomp_suppyrFRB,num_suppyrFRB),
     x hka_suppyrFRB(numcomp_suppyrFRB,num_suppyrFRB),
     x mk2_suppyrFRB(numcomp_suppyrFRB,num_suppyrFRB), 
     x hk2_suppyrFRB(numcomp_suppyrFRB,num_suppyrFRB),
     x mkm_suppyrFRB(numcomp_suppyrFRB,num_suppyrFRB),
     x mkc_suppyrFRB(numcomp_suppyrFRB,num_suppyrFRB),
     x mkahp_suppyrFRB(numcomp_suppyrFRB,num_suppyrFRB),
     x mcat_suppyrFRB(numcomp_suppyrFRB,num_suppyrFRB),
     x hcat_suppyrFRB(numcomp_suppyrFRB,num_suppyrFRB),
     x mcal_suppyrFRB(numcomp_suppyrFRB,num_suppyrFRB),
     x mar_suppyrFRB(numcomp_suppyrFRB,num_suppyrFRB)

       real*8  chi_supbask (numcomp_supbask ,num_supbask )
       real*8  mnaf_supbask (numcomp_supbask ,num_supbask ),
     & mnap_supbask (numcomp_supbask ,num_supbask ),
     x hnaf_supbask (numcomp_supbask ,num_supbask ),
     x mkdr_supbask (numcomp_supbask ,num_supbask ),
     x mka_supbask (numcomp_supbask ,num_supbask ),
     x hka_supbask (numcomp_supbask ,num_supbask ),
     x mk2_supbask (numcomp_supbask ,num_supbask ), 
     x hk2_supbask (numcomp_supbask ,num_supbask ),
     x mkm_supbask (numcomp_supbask ,num_supbask ),
     x mkc_supbask (numcomp_supbask ,num_supbask ),
     x mkahp_supbask (numcomp_supbask ,num_supbask ),
     x mcat_supbask (numcomp_supbask ,num_supbask ),
     x hcat_supbask (numcomp_supbask ,num_supbask ),
     x mcal_supbask (numcomp_supbask ,num_supbask ),
     x mar_supbask (numcomp_supbask ,num_supbask )

       real*8  chi_supng (numcomp_supng ,num_supng )
       real*8  mnaf_supng (numcomp_supng ,num_supng ),
     & mnap_supng (numcomp_supng ,num_supng ),
     x hnaf_supng (numcomp_supng ,num_supng ),
     x mkdr_supng (numcomp_supng ,num_supng ),
     x mka_supng (numcomp_supng ,num_supng ),
     x hka_supng (numcomp_supng ,num_supng ),
     x mk2_supng (numcomp_supng ,num_supng ), 
     x hk2_supng (numcomp_supng ,num_supng ),
     x mkm_supng (numcomp_supng ,num_supng ),
     x mkc_supng (numcomp_supng ,num_supng ),
     x mkahp_supng (numcomp_supng ,num_supng ),
     x mcat_supng (numcomp_supng ,num_supng ),
     x hcat_supng (numcomp_supng ,num_supng ),
     x mcal_supng (numcomp_supng ,num_supng ),
     x mar_supng (numcomp_supng ,num_supng )

       real*8  chi_supaxax (numcomp_supaxax ,num_supaxax )
       real*8  mnaf_supaxax (numcomp_supaxax ,num_supaxax ),
     & mnap_supaxax (numcomp_supaxax ,num_supaxax ),
     x hnaf_supaxax (numcomp_supaxax ,num_supaxax ),
     x mkdr_supaxax (numcomp_supaxax ,num_supaxax ),
     x mka_supaxax (numcomp_supaxax ,num_supaxax ),
     x hka_supaxax (numcomp_supaxax ,num_supaxax ),
     x mk2_supaxax (numcomp_supaxax ,num_supaxax ), 
     x hk2_supaxax (numcomp_supaxax ,num_supaxax ),
     x mkm_supaxax (numcomp_supaxax ,num_supaxax ),
     x mkc_supaxax (numcomp_supaxax ,num_supaxax ),
     x mkahp_supaxax (numcomp_supaxax ,num_supaxax ),
     x mcat_supaxax (numcomp_supaxax ,num_supaxax ),
     x hcat_supaxax (numcomp_supaxax ,num_supaxax ),
     x mcal_supaxax (numcomp_supaxax ,num_supaxax ),
     x mar_supaxax (numcomp_supaxax ,num_supaxax )

       real*8  chi_supLTS(numcomp_supLTS,num_supLTS)
       real*8  mnaf_supLTS(numcomp_supLTS,num_supLTS),
     & mnap_supLTS(numcomp_supLTS,num_supLTS),
     x hnaf_supLTS(numcomp_supLTS,num_supLTS),
     x mkdr_supLTS(numcomp_supLTS,num_supLTS),
     x mka_supLTS(numcomp_supLTS,num_supLTS),
     x hka_supLTS(numcomp_supLTS,num_supLTS),
     x mk2_supLTS(numcomp_supLTS,num_supLTS), 
     x hk2_supLTS(numcomp_supLTS,num_supLTS),
     x mkm_supLTS(numcomp_supLTS,num_supLTS),
     x mkc_supLTS(numcomp_supLTS,num_supLTS),
     x mkahp_supLTS(numcomp_supLTS,num_supLTS),
     x mcat_supLTS(numcomp_supLTS,num_supLTS),
     x hcat_supLTS(numcomp_supLTS,num_supLTS),
     x mcal_supLTS(numcomp_supLTS,num_supLTS),
     x mar_supLTS(numcomp_supLTS,num_supLTS)

      real*8  chi_spinstell(numcomp_spinstell,num_spinstell)
      real*8  mnaf_spinstell(numcomp_spinstell,num_spinstell),
     & mnap_spinstell(numcomp_spinstell,num_spinstell),
     x hnaf_spinstell(numcomp_spinstell,num_spinstell),
     x mkdr_spinstell(numcomp_spinstell,num_spinstell),
     x mka_spinstell(numcomp_spinstell,num_spinstell),
     x hka_spinstell(numcomp_spinstell,num_spinstell),
     x mk2_spinstell(numcomp_spinstell,num_spinstell), 
     x hk2_spinstell(numcomp_spinstell,num_spinstell),
     x mkm_spinstell(numcomp_spinstell,num_spinstell),
     x mkc_spinstell(numcomp_spinstell,num_spinstell),
     x mkahp_spinstell(numcomp_spinstell,num_spinstell),
     x mcat_spinstell(numcomp_spinstell,num_spinstell),
     x hcat_spinstell(numcomp_spinstell,num_spinstell),
     x mcal_spinstell(numcomp_spinstell,num_spinstell),
     x mar_spinstell(numcomp_spinstell,num_spinstell)


       real*8  chi_tuftIB(numcomp_tuftIB,num_tuftIB)
       real*8  mnaf_tuftIB(numcomp_tuftIB,num_tuftIB),
     & mnap_tuftIB(numcomp_tuftIB,num_tuftIB),
     x hnaf_tuftIB(numcomp_tuftIB,num_tuftIB),
     x mkdr_tuftIB(numcomp_tuftIB,num_tuftIB),
     x mka_tuftIB(numcomp_tuftIB,num_tuftIB),
     x hka_tuftIB(numcomp_tuftIB,num_tuftIB),
     x mk2_tuftIB(numcomp_tuftIB,num_tuftIB), 
     x hk2_tuftIB(numcomp_tuftIB,num_tuftIB),
     x mkm_tuftIB(numcomp_tuftIB,num_tuftIB),
     x mkc_tuftIB(numcomp_tuftIB,num_tuftIB),
     x mkahp_tuftIB(numcomp_tuftIB,num_tuftIB),
     x mcat_tuftIB(numcomp_tuftIB,num_tuftIB),
     x hcat_tuftIB(numcomp_tuftIB,num_tuftIB),
     x mcal_tuftIB(numcomp_tuftIB,num_tuftIB),
     x mar_tuftIB(numcomp_tuftIB,num_tuftIB)

       real*8  chi_tuftRS(numcomp_tuftRS,num_tuftRS)
       real*8  mnaf_tuftRS(numcomp_tuftRS,num_tuftRS),
     & mnap_tuftRS(numcomp_tuftRS,num_tuftRS),
     x hnaf_tuftRS(numcomp_tuftRS,num_tuftRS),
     x mkdr_tuftRS(numcomp_tuftRS,num_tuftRS),
     x mka_tuftRS(numcomp_tuftRS,num_tuftRS),
     x hka_tuftRS(numcomp_tuftRS,num_tuftRS),
     x mk2_tuftRS(numcomp_tuftRS,num_tuftRS), 
     x hk2_tuftRS(numcomp_tuftRS,num_tuftRS),
     x mkm_tuftRS(numcomp_tuftRS,num_tuftRS),
     x mkc_tuftRS(numcomp_tuftRS,num_tuftRS),
     x mkahp_tuftRS(numcomp_tuftRS,num_tuftRS),
     x mcat_tuftRS(numcomp_tuftRS,num_tuftRS),
     x hcat_tuftRS(numcomp_tuftRS,num_tuftRS),
     x mcal_tuftRS(numcomp_tuftRS,num_tuftRS),
     x mar_tuftRS(numcomp_tuftRS,num_tuftRS)

       real*8  chi_nontuftRS(numcomp_nontuftRS,num_nontuftRS)
       real*8  mnaf_nontuftRS(numcomp_nontuftRS,num_nontuftRS),
     & mnap_nontuftRS(numcomp_nontuftRS,num_nontuftRS),
     x hnaf_nontuftRS(numcomp_nontuftRS,num_nontuftRS),
     x mkdr_nontuftRS(numcomp_nontuftRS,num_nontuftRS),
     x mka_nontuftRS(numcomp_nontuftRS,num_nontuftRS),
     x hka_nontuftRS(numcomp_nontuftRS,num_nontuftRS),
     x mk2_nontuftRS(numcomp_nontuftRS,num_nontuftRS), 
     x hk2_nontuftRS(numcomp_nontuftRS,num_nontuftRS),
     x mkm_nontuftRS(numcomp_nontuftRS,num_nontuftRS),
     x mkc_nontuftRS(numcomp_nontuftRS,num_nontuftRS),
     x mkahp_nontuftRS(numcomp_nontuftRS,num_nontuftRS),
     x mcat_nontuftRS(numcomp_nontuftRS,num_nontuftRS),
     x hcat_nontuftRS(numcomp_nontuftRS,num_nontuftRS),
     x mcal_nontuftRS(numcomp_nontuftRS,num_nontuftRS),
     x mar_nontuftRS(numcomp_nontuftRS,num_nontuftRS)

       real*8  chi_deepbask(numcomp_deepbask,num_deepbask)
       real*8  mnaf_deepbask(numcomp_deepbask,num_deepbask),
     & mnap_deepbask(numcomp_deepbask,num_deepbask),
     x hnaf_deepbask(numcomp_deepbask,num_deepbask),
     x mkdr_deepbask(numcomp_deepbask,num_deepbask),
     x mka_deepbask(numcomp_deepbask,num_deepbask),
     x hka_deepbask(numcomp_deepbask,num_deepbask),
     x mk2_deepbask(numcomp_deepbask,num_deepbask), 
     x hk2_deepbask(numcomp_deepbask,num_deepbask),
     x mkm_deepbask(numcomp_deepbask,num_deepbask),
     x mkc_deepbask(numcomp_deepbask,num_deepbask),
     x mkahp_deepbask(numcomp_deepbask,num_deepbask),
     x mcat_deepbask(numcomp_deepbask,num_deepbask),
     x hcat_deepbask(numcomp_deepbask,num_deepbask),
     x mcal_deepbask(numcomp_deepbask,num_deepbask),
     x mar_deepbask(numcomp_deepbask,num_deepbask)

       real*8  chi_deepng(numcomp_deepng,num_deepng)
       real*8  mnaf_deepng(numcomp_deepng,num_deepng),
     & mnap_deepng(numcomp_deepng,num_deepng),
     x hnaf_deepng(numcomp_deepng,num_deepng),
     x mkdr_deepng(numcomp_deepng,num_deepng),
     x mka_deepng(numcomp_deepng,num_deepng),
     x hka_deepng(numcomp_deepng,num_deepng),
     x mk2_deepng(numcomp_deepng,num_deepng), 
     x hk2_deepng(numcomp_deepng,num_deepng),
     x mkm_deepng(numcomp_deepng,num_deepng),
     x mkc_deepng(numcomp_deepng,num_deepng),
     x mkahp_deepng(numcomp_deepng,num_deepng),
     x mcat_deepng(numcomp_deepng,num_deepng),
     x hcat_deepng(numcomp_deepng,num_deepng),
     x mcal_deepng(numcomp_deepng,num_deepng),
     x mar_deepng(numcomp_deepng,num_deepng)

       real*8  chi_deepaxax(numcomp_deepaxax,num_deepaxax)
       real*8  mnaf_deepaxax(numcomp_deepaxax,num_deepaxax),
     & mnap_deepaxax(numcomp_deepaxax,num_deepaxax),
     x hnaf_deepaxax(numcomp_deepaxax,num_deepaxax),
     x mkdr_deepaxax(numcomp_deepaxax,num_deepaxax),
     x mka_deepaxax(numcomp_deepaxax,num_deepaxax),
     x hka_deepaxax(numcomp_deepaxax,num_deepaxax),
     x mk2_deepaxax(numcomp_deepaxax,num_deepaxax), 
     x hk2_deepaxax(numcomp_deepaxax,num_deepaxax),
     x mkm_deepaxax(numcomp_deepaxax,num_deepaxax),
     x mkc_deepaxax(numcomp_deepaxax,num_deepaxax),
     x mkahp_deepaxax(numcomp_deepaxax,num_deepaxax),
     x mcat_deepaxax(numcomp_deepaxax,num_deepaxax),
     x hcat_deepaxax(numcomp_deepaxax,num_deepaxax),
     x mcal_deepaxax(numcomp_deepaxax,num_deepaxax),
     x mar_deepaxax(numcomp_deepaxax,num_deepaxax)

       real*8  chi_deepLTS(numcomp_deepLTS,num_deepLTS)
       real*8  mnaf_deepLTS(numcomp_deepLTS,num_deepLTS),
     & mnap_deepLTS(numcomp_deepLTS,num_deepLTS),
     x hnaf_deepLTS(numcomp_deepLTS,num_deepLTS),
     x mkdr_deepLTS(numcomp_deepLTS,num_deepLTS),
     x mka_deepLTS(numcomp_deepLTS,num_deepLTS),
     x hka_deepLTS(numcomp_deepLTS,num_deepLTS),
     x mk2_deepLTS(numcomp_deepLTS,num_deepLTS), 
     x hk2_deepLTS(numcomp_deepLTS,num_deepLTS),
     x mkm_deepLTS(numcomp_deepLTS,num_deepLTS),
     x mkc_deepLTS(numcomp_deepLTS,num_deepLTS),
     x mkahp_deepLTS(numcomp_deepLTS,num_deepLTS),
     x mcat_deepLTS(numcomp_deepLTS,num_deepLTS),
     x hcat_deepLTS(numcomp_deepLTS,num_deepLTS),
     x mcal_deepLTS(numcomp_deepLTS,num_deepLTS),
     x mar_deepLTS(numcomp_deepLTS,num_deepLTS)

       real*8  chi_tcr(numcomp_tcr,num_tcr)
       real*8  mnaf_tcr(numcomp_tcr,num_tcr),
     & mnap_tcr(numcomp_tcr,num_tcr),
     x hnaf_tcr(numcomp_tcr,num_tcr),
     x mkdr_tcr(numcomp_tcr,num_tcr),
     x mka_tcr(numcomp_tcr,num_tcr),
     x hka_tcr(numcomp_tcr,num_tcr),
     x mk2_tcr(numcomp_tcr,num_tcr), 
     x hk2_tcr(numcomp_tcr,num_tcr),
     x mkm_tcr(numcomp_tcr,num_tcr),
     x mkc_tcr(numcomp_tcr,num_tcr),
     x mkahp_tcr(numcomp_tcr,num_tcr),
     x mcat_tcr(numcomp_tcr,num_tcr),
     x hcat_tcr(numcomp_tcr,num_tcr),
     x mcal_tcr(numcomp_tcr,num_tcr),
     x mar_tcr(numcomp_tcr,num_tcr)

       real*8  chi_nRT(numcomp_nRT,num_nRT)
       real*8  mnaf_nRT(numcomp_nRT,num_nRT),
     & mnap_nRT(numcomp_nRT,num_nRT),
     x hnaf_nRT(numcomp_nRT,num_nRT),
     x mkdr_nRT(numcomp_nRT,num_nRT),
     x mka_nRT(numcomp_nRT,num_nRT),
     x hka_nRT(numcomp_nRT,num_nRT),
     x mk2_nRT(numcomp_nRT,num_nRT), 
     x hk2_nRT(numcomp_nRT,num_nRT),
     x mkm_nRT(numcomp_nRT,num_nRT),
     x mkc_nRT(numcomp_nRT,num_nRT),
     x mkahp_nRT(numcomp_nRT,num_nRT),
     x mcat_nRT(numcomp_nRT,num_nRT),
     x hcat_nRT(numcomp_nRT,num_nRT),
     x mcal_nRT(numcomp_nRT,num_nRT),
     x mar_nRT(numcomp_nRT,num_nRT)

       double precision
     &    ranvec_suppyrRS  (num_suppyrRS),
     &    ranvec_suppyrFRB (num_suppyrFRB), 
     &    ranvec_supbask   (num_supbask),  
     &    ranvec_supng     (num_supng  ),  
     &    ranvec_supaxax   (num_supaxax), 
     &    ranvec_supLTS    (num_supLTS), 
     &    ranvec_spinstell (num_spinstell),
     &    ranvec_tuftIB    (num_tuftIB),  
     &    ranvec_tuftRS    (num_tuftRS), 
     &    ranvec_nontuftRS (num_nontuftRS),
     &    ranvec_deepbask  (num_deepbask),
     &    ranvec_deepng    (num_deepng  ),
     &    ranvec_deepaxax  (num_deepaxax),
     &    ranvec_deepLTS   (num_deepLTS),
     &    ranvec_TCR       (num_TCR),   
     &    ranvec_nRT       (num_nRT),
     &    seed /137.d0/

c Define arrays for distal axon voltages which will be shared
c between nodes, and for axonal sites of possible gj
         double precision::
     &  distal_axon_suppyrRS  (maxcellspernode),
     &  ldistal_axon_suppyrRS (num_suppyrRS), ! use for outtime
     &      gj_axon_suppyrRS  (maxcellspernode),
     &  distal_axon_suppyrFRB (maxcellspernode),
     &  ldistal_axon_suppyrFRB(num_suppyrFRB),
     &      gj_axon_suppyrFRB (maxcellspernode),
     &  distal_axon_supbask   (maxcellspernode),
     &  ldistal_axon_supbask  (num_supbask),
     &      gj_axon_supbask   (maxcellspernode),
     &  distal_axon_supng     (maxcellspernode),
     &  ldistal_axon_supng    (num_supng  ),
     &      gj_axon_supng     (maxcellspernode),
     &  distal_axon_supaxax   (maxcellspernode),
     &  ldistal_axon_supaxax  (num_supaxax),
     &      gj_axon_supaxax   (maxcellspernode),
     &  distal_axon_supLTS    (maxcellspernode),
     &  ldistal_axon_supLTS   (num_supLTS),
     &      gj_axon_supLTS    (maxcellspernode) 
         double precision::
     &  distal_axon_spinstell (maxcellspernode),
     &  ldistal_axon_spinstell(num_spinstell),
     &      gj_axon_spinstell (maxcellspernode),
     &  distal_axon_tuftIB    (maxcellspernode),
     &  ldistal_axon_tuftIB   (num_tuftIB),
     &      gj_axon_tuftIB    (maxcellspernode),
     &  distal_axon_tuftRS    (maxcellspernode),
     &  ldistal_axon_tuftRS   (num_tuftRS),
     &      gj_axon_tuftRS    (maxcellspernode),
     &  distal_axon_nontuftRS (maxcellspernode),
     &  ldistal_axon_nontuftRS(num_nontuftRS),
     &      gj_axon_nontuftRS (maxcellspernode),
     &  distal_axon_deepbask  (maxcellspernode),
     &  ldistal_axon_deepbask (num_deepbask),
     &      gj_axon_deepbask  (maxcellspernode),
     &  distal_axon_deepng    (maxcellspernode),
     &  ldistal_axon_deepng   (num_deepng  ),
     &      gj_axon_deepng    (maxcellspernode),
     &  distal_axon_deepaxax  (maxcellspernode),
     &  ldistal_axon_deepaxax (num_deepaxax),
     &      gj_axon_deepaxax  (maxcellspernode),
     &  distal_axon_deepLTS   (maxcellspernode),
     &  ldistal_axon_deepLTS  (num_deepLTS),
     &      gj_axon_deepLTS   (maxcellspernode),
     &  distal_axon_TCR       (maxcellspernode),
     &  ldistal_axon_TCR      (num_TCR),
     &      gj_axon_TCR       (maxcellspernode),
     &  distal_axon_nRT       (maxcellspernode),
     &  ldistal_axon_nRT      (num_nRT),
     &      gj_axon_nRT       (maxcellspernode),
!    Communication will be complicated, however, because - say - a tuftIB
!   will have to communicate only the tuftIB axons it has integrated.
     &  distal_axon_global    (numnodes  * maxcellspernode),
     &      gj_axon_global    (numnodes  * maxcellspernode)
! distal_axon_global will be concatenation of individual
! distal_axon vectors       

! define arrays for axonal voltges, needed for mixed gj
! PROBABLY should organize this as per distal_axon...
! ALSO must consider how to handle interneuron gj, in case interneurons
! spread across multiple nodes...
c        double precision ::
c    &    vax_suppyrRS (num_suppyrRS), vax_suppyrFRB (num_suppyrFRB),
c    &    vax_tuftIB (num_tuftIB), vax_tuftRS (num_tuftRS)

         double precision::
     &  outtime_suppyrRS  (5000, num_suppyrRS),
     &  outtime_suppyrFRB (5000, num_suppyrFRB),
     &  outtime_supbask   (5000, num_supbask), 
     &  outtime_supng     (5000, num_supng  ), 
     &  outtime_supaxax   (5000, num_supaxax), 
     &  outtime_supLTS    (5000, num_supLTS),   
     &  outtime_spinstell (5000, num_spinstell), 
     &  outtime_tuftIB    (5000, num_tuftIB), 
     &  outtime_tuftRS    (5000, num_tuftRS),  
     &  outtime_nontuftRS (5000, num_nontuftRS),
     &  outtime_deepbask  (5000, num_deepbask),
     &  outtime_deepng    (5000, num_deepng  ),
     &  outtime_deepaxax  (5000, num_deepaxax),
     &  outtime_deepLTS   (5000, num_deepLTS), 
     &  outtime_TCR       (5000, num_TCR),      
     &  outtime_nRT       (5000, num_nRT)       

         INTEGER
     &  outctr_suppyrRS  (num_suppyrRS), 
     &  outctr_suppyrFRB (num_suppyrFRB),
     &  outctr_supbask   (num_supbask), 
     &  outctr_supng     (num_supng  ), 
     &  outctr_supaxax   (num_supaxax),
     &  outctr_supLTS    (num_supLTS),
     &  outctr_spinstell (num_spinstell),
     &  outctr_tuftIB    (num_tuftIB), 
     &  outctr_tuftRS    (num_tuftRS),
     &  outctr_nontuftRS (num_nontuftRS),
     &  outctr_deepbask  (num_deepbask),
     &  outctr_deepng    (num_deepng  ),
     &  outctr_deepaxax  (num_deepaxax),
     &  outctr_deepLTS   (num_deepLTS),
     &  outctr_TCR       (num_TCR), 
     &  outctr_nRT       (num_nRT)

        CHARACTER(LEN=9) nodecell(0:numnodes-1) ! will define which cell type is to be handled by each node

        INTEGER place(0:numnodes-1)  ! this will define whether a node is 1st, 2nd... in the set of nodes
! used by a given type of cell

        integer initialize, firstcell, lastcell ! used in integration calls 
        integer ictr, ioffset

       REAL*8 gettime, time1, time2, time, timtot
       REAL*8 presyntime, delta, dexparg, dexparg1, dexparg2
       INTEGER thisno, display /0/, O
       REAL*8 z, z1, z2, outrcd(20), z3, z4, z3a, z4a, z5, z6, z7
       REAL*8 z10, z11, z12, z13, z14, z10a, z10b
       INTEGER i, j, k, L, k0, m

       double precision scale_tuftIB_gNaP(61) 
       double precision scale_tuftIB_gKM(61), Mshift ! for shifting gKM rate functions.
       double precision scale_tuftIB_gCaL (num_tuftIB)
       double precision gCaL_tuftIB(numcomp_tuftIB, num_tuftIB)
! declare this gCaL here, because there are problems in integration routine in
! making sure this conductance gets saved
       double precision rel_axonshift_tuftIB, rel_axonshift_suppyrRS,
     &    rel_axonshift_suppyrFRB

        double precision scale_suppyrFRB_gNaP(74)

c START EXECUTION PHASE
          include 'mpif.h'
          call mpi_init (info)
          call mpi_comm_rank(mpi_comm_world, thisno, info)
          call mpi_comm_size(mpi_comm_world, nodes , info)
          time1 = gettime()

          do i = 1, 74 
           scale_suppyrFRB_gNaP(i) = 0.65d0
          end do

c Define gCaL scaling for tuftIB - depends on cell rather than compartment
       call durand(seed,num_tuftIB,ranvec_tuftIB)
          do L = 1, num_tuftIB
           scale_tuftIB_gCaL(L) =
c    &   0.20d0 + 0.10d0 * ranvec_tuftIB(L) 
     &   0.35d0 + 0.10d0 * ranvec_tuftIB(L) 
c    &   1.60d0 + 0.40d0 * ranvec_tuftIB(L) 
c    &   0.00d0 + 0.00d0 * ranvec_tuftIB(L) 
          end do

c Define variable for shifting gKM rate functions in tuftIB
          Mshift =  0.d0

c Define gKM scaling for tufted IB pyramids
         do i = 1, 55  ! soma  & dendrites
c          scale_tuftIB_gKM(i) = 1.00d0
!          scale_tuftIB_gKM(i) = 0.30d0
c          scale_tuftIB_gKM(i) = 0.40d0
c          scale_tuftIB_gKM(i) = 0.10d0
c          scale_tuftIB_gKM(i) = 0.05d0
           scale_tuftIB_gKM(i) = 0.03d0
           scale_tuftIB_gNaP(i) = 0.0d0
         end do
         do i = 56, 61  ! axon
c          scale_tuftIB_gKM(i) = 1.00d0
!          scale_tuftIB_gKM(i) = 0.50d0
c          scale_tuftIB_gKM(i) = 0.40d0
c          scale_tuftIB_gKM(i) = 0.10d0
           scale_tuftIB_gKM(i) = 0.00d0
c          scale_tuftIB_gKM(i) = 0.05d0
c          scale_tuftIB_gNaP(i) = 1.0d0
           scale_tuftIB_gNaP(i) = 0.0d0
         end do

c Define which cell type is handled by each processor
           nodecell(0) = 'suppyrRS '
           nodecell(1) = 'suppyrRS '
           nodecell(2) = 'suppyrRS '
           nodecell(3) = 'suppyrRS '
           nodecell(4) = 'suppyrFRB'
           nodecell(5) = 'supbask  '
           nodecell(6) = 'supng    '
           nodecell(7) = 'supaxax  '
           nodecell(8) = 'supLTS   '
           nodecell(9) = 'spinstell'
           nodecell(10) = 'tuftIB   '
           nodecell(11)= 'tuftIB   '
           nodecell(12)= 'tuftIB   '
           nodecell(13)= 'tuftIB   '
           nodecell(14)= 'tuftIB   '
           nodecell(15)= 'tuftIB   '
c          nodecell(16)= 'tuftIB   '
c          nodecell(17)= 'tuftIB   '
c          nodecell(18)= 'tuftRS   '
           nodecell(16)= 'nontuftRS'
           nodecell(17)= 'nontuftRS'
           nodecell(18)= 'deepbask '
           nodecell(19)= 'deepng   '
           nodecell(20)= 'deepaxax '
           nodecell(21)= 'deepLTS  '
           nodecell(22)= 'TCR      '
           nodecell(23)= 'nRT      '
          if (thisno.eq.0) then
            do i = 0, numnodes - 1
              write(6,786) i, nodecell(i)
786           format(i5,a10)
            end do
          end if

c Define "rank" of nodes assigned to each cell-type - will
c be used in figuring out how to partition the cells.
           place( 0) = 1  ! suppyrRS: 1
           place( 1) = 2  ! suppyrRS: 2
           place( 2) = 3  ! suppyrRS: 3
           place( 3) = 4  ! suppyrRS: 4
           place( 4) = 1  ! suppyrFRB 
           place( 5) = 1  ! supbask   
           place( 6) = 1  ! supng     
           place( 7) = 1  ! supaxax   
           place( 8) = 1  ! supLTS    
           place( 9) = 1  ! spinstell 
           place(10) = 1  ! tuftIB: 1 
           place(11) = 2  ! tuftIB: 2 
           place(12) = 3  ! tuftIB: 3 
           place(13) = 4  ! tuftIB: 4 
           place(14) = 5  ! tuftIB: 5 
c          place(15) = 6  ! tuftIB: 6 
c          place(16) = 7  ! tuftIB: 7   
c          place(17) = 8  ! tuftIB: 8   
           place(15) = 1  ! tuftRS      
           place(16) = 1  ! nontuftRS: 1
           place(17) = 2  ! nontuftRS: 2
           place(18) = 1  ! deepbask    
           place(19) = 1  ! deepng      
           place(20) = 1  ! deepaxax    
           place(21) = 1  ! deepLTS     
           place(22) = 1  ! TCR         
           place(23) = 1  ! nRT         

         do i = 1, 5000
           do j = 1, num_suppyrRS
        outtime_suppyrRS(i,j)             = -1.d5
           end do ! j
           do j = 1, num_suppyrFRB
        outtime_suppyrFRB(i,j)            = -1.d5 
           end do ! j
           do j = 1, num_supbask  
        outtime_supbask(i,j)              = -1.d5
           end do ! j
           do j = 1, num_supng    
        outtime_supng  (i,j)              = -1.d5
           end do ! j
           do j = 1, num_supaxax  
        outtime_supaxax(i,j)              = -1.d5
           end do ! j
           do j = 1, num_supLTS   
        outtime_supLTS(i,j)               = -1.d5
           end do ! j
           do j = 1, num_spinstell
        outtime_spinstell(i,j)            = -1.d5 
           end do ! j
           do j = 1, num_tuftIB   
        outtime_tuftIB(i,j)               = -1.d5
           end do ! j
           do j = 1, num_tuftRS   
        outtime_tuftRS(i,j)               = -1.d5
           end do ! j
           do j = 1, num_nontuftRS   
        outtime_nontuftRS(i,j)            = -1.d5
           end do ! j
           do j = 1, num_deepbask    
        outtime_deepbask(i,j)             = -1.d5
           end do ! j
           do j = 1, num_deepng      
        outtime_deepng  (i,j)             = -1.d5
           end do ! j
           do j = 1, num_deepaxax    
        outtime_deepaxax(i,j)             = -1.d5
           end do ! j
           do j = 1, num_deepLTS     
        outtime_deepLTS(i,j)              = -1.d5
           end do ! j
           do j = 1, num_TCR         
        outtime_TCR(i,j)                  = -1.d5
           end do ! j
           do j = 1, num_nRT         
        outtime_nRT(i,j)                  = -1.d5
           end do ! j
         end do ! do i

c         timtot = 125.d0 
c         timtot = 1750.d0
          timtot = 3000.d0
c         timtot = 0.d0

c Setup tables for calculating exponentials
          call dexptablesmall_setup (dexptablesmall)
          call dexptablebig_setup   (dexptablebig)
          call otis_table_setup (otis_table,how_often,dt)

c Compartments contacted by axoaxonic interneurons are IS only
          do i = 1, num_suppyrRS 
          do j = 1, num_supaxax_to_suppyrRS 
             com_supaxax_to_suppyrRS (j,i) = 69
          end do
          end do
          do i = 1, num_suppyrFRB
          do j = 1, num_supaxax_to_suppyrFRB
             com_supaxax_to_suppyrFRB(j,i) = 69
          end do
          end do
          do i = 1, num_spinstell
          do j = 1, num_supaxax_to_spinstell
             com_supaxax_to_spinstell(j,i) = 54
          end do
          end do
          do i = 1, num_tuftIB   
          do j = 1, num_supaxax_to_tuftIB   
             com_supaxax_to_tuftIB   (j,i) = 56
          end do
          end do
          do i = 1, num_tuftRS   
          do j = 1, num_supaxax_to_tuftRS   
             com_supaxax_to_tuftRS   (j,i) = 56
          end do
          end do
          do i = 1, num_nontuftRS   
          do j = 1, num_supaxax_to_nontuftRS   
             com_supaxax_to_nontuftRS   (j,i) = 45
          end do
          end do
          do i = 1, num_suppyrRS    
          do j = 1, num_deepaxax_to_suppyrRS    
             com_deepaxax_to_suppyrRS    (j,i) = 69
          end do
          end do
          do i = 1, num_suppyrFRB   
          do j = 1, num_deepaxax_to_suppyrFRB   
             com_deepaxax_to_suppyrFRB   (j,i) = 69
          end do
          end do
          do i = 1, num_spinstell   
          do j = 1, num_deepaxax_to_spinstell   
             com_deepaxax_to_spinstell   (j,i) = 54
          end do
          end do
          do i = 1, num_tuftIB      
          do j = 1, num_deepaxax_to_tuftIB      
             com_deepaxax_to_tuftIB      (j,i) = 56 
          end do
          end do
          do i = 1, num_tuftRS      
          do j = 1, num_deepaxax_to_tuftRS      
             com_deepaxax_to_tuftRS      (j,i) = 56 
          end do
          end do
          do i = 1, num_nontuftRS      
          do j = 1, num_deepaxax_to_nontuftRS      
             com_deepaxax_to_nontuftRS      (j,i) = 45 
          end do
          end do
c End section on making axoaxonic cells connect to IS's

c Construct synaptic connectivity tables
                display = 0

          CALL synaptic_map_construct (thisno,
     &     num_suppyrRS, num_suppyrRS,           
     &     map_suppyrRS_to_suppyrRS,
     &     num_suppyrRS_to_suppyrRS,    display)
          CALL synaptic_map_construct (thisno,
     &     num_suppyrRS, num_suppyrFRB,          
     &     map_suppyrRS_to_suppyrFRB,
     &     num_suppyrRS_to_suppyrFRB,   display)
          CALL synaptic_map_construct (thisno,
     &     num_suppyrRS, num_supbask,            
     &     map_suppyrRS_to_supbask,  
     &     num_suppyrRS_to_supbask,     display)
          CALL synaptic_map_construct (thisno,
     &     num_suppyrRS, num_supng  ,            
     &     map_suppyrRS_to_supng  ,  
     &     num_suppyrRS_to_supng  ,     display)
          CALL synaptic_map_construct (thisno,
     &     num_suppyrRS, num_supaxax,            
     &     map_suppyrRS_to_supaxax,  
     &     num_suppyrRS_to_supaxax,     display)
          CALL synaptic_map_construct (thisno,
     &     num_suppyrRS, num_supLTS,             
     &     map_suppyrRS_to_supLTS,   
     &     num_suppyrRS_to_supLTS,      display)
          CALL synaptic_map_construct (thisno,
     &     num_suppyrRS, num_spinstell,          
     &     map_suppyrRS_to_spinstell,
     &     num_suppyrRS_to_spinstell,   display)
          CALL synaptic_map_construct (thisno,
     &     num_suppyrRS, num_tuftIB,             
     &     map_suppyrRS_to_tuftIB,   
     &     num_suppyrRS_to_tuftIB,      display)
          CALL synaptic_map_construct (thisno,
     &     num_suppyrRS, num_tuftRS,             
     &     map_suppyrRS_to_tuftRS,   
     &     num_suppyrRS_to_tuftRS,      display)
          CALL synaptic_map_construct (thisno,
     &     num_suppyrRS, num_deepbask,           
     &     map_suppyrRS_to_deepbask, 
     &     num_suppyrRS_to_deepbask,    display)
          CALL synaptic_map_construct (thisno,
     &     num_suppyrRS, num_deepaxax,           
     &     map_suppyrRS_to_deepaxax, 
     &     num_suppyrRS_to_deepaxax,    display)
          CALL synaptic_map_construct (thisno,
     &     num_suppyrRS, num_deepLTS,            
     &     map_suppyrRS_to_deepLTS,  
     &     num_suppyrRS_to_deepLTS,     display)
          CALL synaptic_map_construct (thisno,
     &     num_suppyrRS, num_nontuftRS,          
     &     map_suppyrRS_to_nontuftRS,
     &     num_suppyrRS_to_nontuftRS,   display)

          CALL synaptic_map_construct (thisno,
     &     num_suppyrFRB, num_suppyrRS,           
     &     map_suppyrFRB_to_suppyrRS, 
     &     num_suppyrFRB_to_suppyrRS,    display)
          CALL synaptic_map_construct (thisno,
     &     num_suppyrFRB, num_suppyrFRB,          
     &     map_suppyrFRB_to_suppyrFRB,
     &     num_suppyrFRB_to_suppyrFRB,   display)
          CALL synaptic_map_construct (thisno,
     &     num_suppyrFRB, num_supbask,            
     &     map_suppyrFRB_to_supbask,  
     &     num_suppyrFRB_to_supbask,     display)
          CALL synaptic_map_construct (thisno,
     &     num_suppyrFRB, num_supng  ,            
     &     map_suppyrFRB_to_supng  ,  
     &     num_suppyrFRB_to_supng  ,     display)
          CALL synaptic_map_construct (thisno,
     &     num_suppyrFRB, num_supaxax,            
     &     map_suppyrFRB_to_supaxax,  
     &     num_suppyrFRB_to_supaxax,     display)
          CALL synaptic_map_construct (thisno,
     &     num_suppyrFRB, num_supLTS,             
     &     map_suppyrFRB_to_supLTS,   
     &     num_suppyrFRB_to_supLTS,      display)
          CALL synaptic_map_construct (thisno,
     &     num_suppyrFRB, num_spinstell,          
     &     map_suppyrFRB_to_spinstell,
     &     num_suppyrFRB_to_spinstell,   display)
          CALL synaptic_map_construct (thisno,
     &     num_suppyrFRB, num_tuftIB,             
     &     map_suppyrFRB_to_tuftIB,   
     &     num_suppyrFRB_to_tuftIB,      display)
          CALL synaptic_map_construct (thisno,
     &     num_suppyrFRB, num_tuftRS,             
     &     map_suppyrFRB_to_tuftRS,   
     &     num_suppyrFRB_to_tuftRS,      display)
          CALL synaptic_map_construct (thisno,
     &     num_suppyrFRB, num_deepbask,           
     &     map_suppyrFRB_to_deepbask, 
     &     num_suppyrFRB_to_deepbask,    display)
          CALL synaptic_map_construct (thisno,
     &     num_suppyrFRB, num_deepaxax,           
     &     map_suppyrFRB_to_deepaxax, 
     &     num_suppyrFRB_to_deepaxax,    display)
          CALL synaptic_map_construct (thisno,
     &     num_suppyrFRB, num_deepLTS,            
     &     map_suppyrFRB_to_deepLTS,  
     &     num_suppyrFRB_to_deepLTS,     display)
          CALL synaptic_map_construct (thisno,
     &     num_suppyrFRB, num_nontuftRS,          
     &     map_suppyrFRB_to_nontuftRS,
     &     num_suppyrFRB_to_nontuftRS,   display)

          CALL synaptic_map_construct (thisno,
     &     num_supbask, num_suppyrRS,           
     &     map_supbask_to_suppyrRS, 
     &     num_supbask_to_suppyrRS,   display)
          CALL synaptic_map_construct (thisno,
     &     num_supbask, num_suppyrFRB,          
     &     map_supbask_to_suppyrFRB,
     &     num_supbask_to_suppyrFRB,  display)
          CALL synaptic_map_construct (thisno,
     &     num_supbask, num_supbask,            
     &     map_supbask_to_supbask,  
     &     num_supbask_to_supbask,    display)
          CALL synaptic_map_construct (thisno,
     &     num_supbask, num_supng  ,            
     &     map_supbask_to_supng  ,  
     &     num_supbask_to_supng  ,    display)
          CALL synaptic_map_construct (thisno,
     &     num_supbask, num_supaxax,            
     &     map_supbask_to_supaxax,  
     &     num_supbask_to_supaxax,    display)
          CALL synaptic_map_construct (thisno,
     &     num_supbask, num_supLTS,             
     &     map_supbask_to_supLTS,   
     &     num_supbask_to_supLTS,     display)
          CALL synaptic_map_construct (thisno,
     &     num_supbask, num_spinstell,          
     &     map_supbask_to_spinstell,
     &     num_supbask_to_spinstell,  display)

          CALL synaptic_map_construct (thisno,
     &     num_supng  , num_suppyrRS ,          
     &     map_supng_to_suppyrRS ,
     &     num_supng_to_suppyrRS ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_supng  , num_suppyrFRB,          
     &     map_supng_to_suppyrFRB,
     &     num_supng_to_suppyrFRB,  display)
          CALL synaptic_map_construct (thisno,
     &     num_supng  , num_nontuftRS,          
     &     map_supng_to_nontuftRS,
     &     num_supng_to_nontuftRS,  display)
          CALL synaptic_map_construct (thisno,
     &     num_supng  , num_tuftIB   ,          
     &     map_supng_to_tuftIB   ,
     &     num_supng_to_tuftIB   ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_supng  , num_tuftRS   ,          
     &     map_supng_to_tuftRS   ,
     &     num_supng_to_tuftRS   ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_supng  , num_supng    ,          
     &     map_supng_to_supng    ,
     &     num_supng_to_supng    ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_supng  , num_supbask  ,          
     &     map_supng_to_supbask  ,
     &     num_supng_to_supbask  ,  display)

          CALL synaptic_map_construct (thisno,
     &     num_supaxax, num_suppyrRS,           
     &     map_supaxax_to_suppyrRS, 
     &     num_supaxax_to_suppyrRS,   display)
          CALL synaptic_map_construct (thisno,
     &     num_supaxax, num_suppyrFRB,          
     &     map_supaxax_to_suppyrFRB,
     &     num_supaxax_to_suppyrFRB,  display)
          CALL synaptic_map_construct (thisno,
     &     num_supaxax, num_spinstell,          
     &     map_supaxax_to_spinstell,
     &     num_supaxax_to_spinstell,  display)
          CALL synaptic_map_construct (thisno,
     &     num_supaxax, num_tuftIB,             
     &     map_supaxax_to_tuftIB,   
     &     num_supaxax_to_tuftIB,     display)
          CALL synaptic_map_construct (thisno,
     &     num_supaxax, num_tuftRS,             
     &     map_supaxax_to_tuftRS,   
     &     num_supaxax_to_tuftRS,     display)
          CALL synaptic_map_construct (thisno,
     &     num_supaxax, num_nontuftRS,             
     &     map_supaxax_to_nontuftRS,   
     &     num_supaxax_to_nontuftRS,  display)

          CALL synaptic_map_construct (thisno,
     &     num_supLTS,  num_suppyrRS,              
     &     map_supLTS_to_suppyrRS,    
     &     num_supLTS_to_suppyrRS ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_supLTS,  num_suppyrFRB,             
     &     map_supLTS_to_suppyrFRB,   
     &     num_supLTS_to_suppyrFRB,  display)
          CALL synaptic_map_construct (thisno,
     &     num_supLTS,  num_supbask,               
     &     map_supLTS_to_supbask,     
     &     num_supLTS_to_supbask,    display)
          CALL synaptic_map_construct (thisno,
     &     num_supLTS,  num_supaxax,               
     &     map_supLTS_to_supaxax,     
     &     num_supLTS_to_supaxax,    display)
          CALL synaptic_map_construct (thisno,
     &     num_supLTS,  num_supLTS,                
     &     map_supLTS_to_supLTS,      
     &     num_supLTS_to_supLTS,     display)
          CALL synaptic_map_construct (thisno,
     &     num_supLTS,  num_spinstell,             
     &     map_supLTS_to_spinstell,   
     &     num_supLTS_to_spinstell,  display)
          CALL synaptic_map_construct (thisno,
     &     num_supLTS,  num_tuftIB,                
     &     map_supLTS_to_tuftIB,      
     &     num_supLTS_to_tuftIB   ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_supLTS,  num_tuftRS,                
     &     map_supLTS_to_tuftRS,      
     &     num_supLTS_to_tuftRS   ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_supLTS,  num_deepbask,              
     &     map_supLTS_to_deepbask,    
     &     num_supLTS_to_deepbask ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_supLTS,  num_deepaxax,              
     &     map_supLTS_to_deepaxax,    
     &     num_supLTS_to_deepaxax ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_supLTS,  num_deepLTS,               
     &     map_supLTS_to_deepLTS,     
     &     num_supLTS_to_deepLTS,    display)
          CALL synaptic_map_construct (thisno,
     &     num_supLTS,  num_nontuftRS,             
     &     map_supLTS_to_nontuftRS,   
     &     num_supLTS_to_nontuftRS,  display)

          CALL synaptic_map_construct (thisno,
     &     num_spinstell,  num_suppyrRS,              
     &     map_spinstell_to_suppyrRS,    
     &     num_spinstell_to_suppyrRS,   display)
          CALL synaptic_map_construct (thisno,
     &     num_spinstell,  num_suppyrFRB,             
     &     map_spinstell_to_suppyrFRB,   
     &     num_spinstell_to_suppyrFRB,  display)
          CALL synaptic_map_construct (thisno,
     &     num_spinstell,  num_supbask,               
     &     map_spinstell_to_supbask,     
     &     num_spinstell_to_supbask,    display)
          CALL synaptic_map_construct (thisno,
     &     num_spinstell,  num_supaxax,               
     &     map_spinstell_to_supaxax,     
     &     num_spinstell_to_supaxax,    display)
          CALL synaptic_map_construct (thisno,
     &     num_spinstell,  num_supLTS,                
     &     map_spinstell_to_supLTS,      
     &     num_spinstell_to_supLTS,     display)
          CALL synaptic_map_construct (thisno,
     &     num_spinstell,  num_spinstell,             
     &     map_spinstell_to_spinstell,   
     &     num_spinstell_to_spinstell,  display)
          CALL synaptic_map_construct (thisno,
     &     num_spinstell,  num_tuftIB,                
     &     map_spinstell_to_tuftIB,      
     &     num_spinstell_to_tuftIB,     display)
          CALL synaptic_map_construct (thisno,
     &     num_spinstell,  num_tuftRS,                
     &     map_spinstell_to_tuftRS,      
     &     num_spinstell_to_tuftRS,     display)
          CALL synaptic_map_construct (thisno,
     &     num_spinstell,  num_deepbask,              
     &     map_spinstell_to_deepbask,    
     &     num_spinstell_to_deepbask,   display)
          CALL synaptic_map_construct (thisno,
     &     num_spinstell,  num_deepng  ,              
     &     map_spinstell_to_deepng  ,    
     &     num_spinstell_to_deepng  ,   display)
          CALL synaptic_map_construct (thisno,
     &     num_spinstell,  num_deepaxax,              
     &     map_spinstell_to_deepaxax,    
     &     num_spinstell_to_deepaxax,   display)
          CALL synaptic_map_construct (thisno,
     &     num_spinstell,  num_deepLTS,               
     &     map_spinstell_to_deepLTS,     
     &     num_spinstell_to_deepLTS,    display)
          CALL synaptic_map_construct (thisno,
     &     num_spinstell,  num_nontuftRS,             
     &     map_spinstell_to_nontuftRS,   
     &     num_spinstell_to_nontuftRS,  display)

          CALL synaptic_map_construct (thisno,
     &     num_tuftIB,  num_suppyrRS,              
     &     map_tuftIB_to_suppyrRS,    
     &     num_tuftIB_to_suppyrRS,   display)
          CALL synaptic_map_construct (thisno,
     &     num_tuftIB,  num_suppyrFRB,             
     &     map_tuftIB_to_suppyrFRB,   
     &     num_tuftIB_to_suppyrFRB,  display)
          CALL synaptic_map_construct (thisno,
     &     num_tuftIB,  num_supbask,               
     &     map_tuftIB_to_supbask,     
     &     num_tuftIB_to_supbask,    display)
          CALL synaptic_map_construct (thisno,
     &     num_tuftIB,  num_supaxax,               
     &     map_tuftIB_to_supaxax,     
     &     num_tuftIB_to_supaxax,    display)
          CALL synaptic_map_construct (thisno,
     &     num_tuftIB,  num_supLTS,                
     &     map_tuftIB_to_supLTS,      
     &     num_tuftIB_to_supLTS,     display)
          CALL synaptic_map_construct (thisno,
     &     num_tuftIB,  num_spinstell,             
     &     map_tuftIB_to_spinstell,   
     &     num_tuftIB_to_spinstell,  display)
          CALL synaptic_map_construct (thisno,
     &     num_tuftIB,  num_tuftIB   ,             
     &     map_tuftIB_to_tuftIB   ,   
     &     num_tuftIB_to_tuftIB   ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_tuftIB,  num_tuftRS   ,             
     &     map_tuftIB_to_tuftRS   ,   
     &     num_tuftIB_to_tuftRS   ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_tuftIB,  num_deepbask ,             
     &     map_tuftIB_to_deepbask ,   
     &     num_tuftIB_to_deepbask ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_tuftIB,  num_deepng   ,             
     &     map_tuftIB_to_deepng   ,   
     &     num_tuftIB_to_deepng   ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_tuftIB,  num_deepaxax ,             
     &     map_tuftIB_to_deepaxax ,   
     &     num_tuftIB_to_deepaxax ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_tuftIB,  num_deepLTS  ,             
     &     map_tuftIB_to_deepLTS  ,   
     &     num_tuftIB_to_deepLTS  ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_tuftIB,  num_nontuftRS,             
     &     map_tuftIB_to_nontuftRS,   
     &     num_tuftIB_to_nontuftRS,  display)

          CALL synaptic_map_construct (thisno,
     &     num_tuftRS,  num_suppyrRS ,             
     &     map_tuftRS_to_suppyrRS ,   
     &     num_tuftRS_to_suppyrRS ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_tuftRS,  num_suppyrFRB,             
     &     map_tuftRS_to_suppyrFRB,   
     &     num_tuftRS_to_suppyrFRB,  display)
          CALL synaptic_map_construct (thisno,
     &     num_tuftRS,  num_supbask  ,             
     &     map_tuftRS_to_supbask  ,   
     &     num_tuftRS_to_supbask  ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_tuftRS,  num_supaxax  ,             
     &     map_tuftRS_to_supaxax  ,   
     &     num_tuftRS_to_supaxax  ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_tuftRS,  num_supLTS   ,             
     &     map_tuftRS_to_supLTS   ,   
     &     num_tuftRS_to_supLTS   ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_tuftRS,  num_spinstell,             
     &     map_tuftRS_to_spinstell,   
     &     num_tuftRS_to_spinstell,  display)
          CALL synaptic_map_construct (thisno,
     &     num_tuftRS,  num_tuftIB   ,             
     &     map_tuftRS_to_tuftIB   ,   
     &     num_tuftRS_to_tuftIB   ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_tuftRS,  num_tuftRS   ,             
     &     map_tuftRS_to_tuftRS   ,   
     &     num_tuftRS_to_tuftRS   ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_tuftRS,  num_deepbask ,             
     &     map_tuftRS_to_deepbask ,   
     &     num_tuftRS_to_deepbask ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_tuftRS,  num_deepng   ,             
     &     map_tuftRS_to_deepng   ,   
     &     num_tuftRS_to_deepng   ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_tuftRS,  num_deepaxax ,             
     &     map_tuftRS_to_deepaxax ,   
     &     num_tuftRS_to_deepaxax ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_tuftRS,  num_deepLTS  ,             
     &     map_tuftRS_to_deepLTS  ,   
     &     num_tuftRS_to_deepLTS  ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_tuftRS,  num_nontuftRS,             
     &     map_tuftRS_to_nontuftRS,   
     &     num_tuftRS_to_nontuftRS,  display)

          CALL synaptic_map_construct (thisno,
     &     num_deepbask,  num_spinstell,             
     &     map_deepbask_to_spinstell,   
     &     num_deepbask_to_spinstell,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepbask,  num_tuftIB   ,             
     &     map_deepbask_to_tuftIB   ,   
     &     num_deepbask_to_tuftIB   ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepbask,  num_tuftRS   ,             
     &     map_deepbask_to_tuftRS   ,   
     &     num_deepbask_to_tuftRS   ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepbask,  num_deepbask ,             
     &     map_deepbask_to_deepbask ,   
     &     num_deepbask_to_deepbask ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepbask,  num_deepng   ,             
     &     map_deepbask_to_deepng   ,   
     &     num_deepbask_to_deepng   ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepbask,  num_deepaxax ,             
     &     map_deepbask_to_deepaxax ,   
     &     num_deepbask_to_deepaxax ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepbask,  num_deepLTS  ,             
     &     map_deepbask_to_deepLTS  ,   
     &     num_deepbask_to_deepLTS  ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepbask,  num_nontuftRS,             
     &     map_deepbask_to_nontuftRS,   
     &     num_deepbask_to_nontuftRS,  display)

          CALL synaptic_map_construct (thisno,
     &     num_deepng  ,  num_tuftIB   ,             
     &     map_deepng_to_tuftIB   ,   
     &     num_deepng_to_tuftIB   ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepng  ,  num_tuftRS   ,             
     &     map_deepng_to_tuftRS   ,   
     &     num_deepng_to_tuftRS   ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepng  ,  num_nontuftRS,             
     &     map_deepng_to_nontuftRS,   
     &     num_deepng_to_nontuftRS,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepng  ,  num_spinstell,             
     &     map_deepng_to_spinstell,   
     &     num_deepng_to_spinstell,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepng  ,  num_deepng   ,             
     &     map_deepng_to_deepng   ,   
     &     num_deepng_to_deepng   ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepng  ,  num_deepbask ,             
     &     map_deepng_to_deepbask ,   
     &     num_deepng_to_deepbask ,  display)

          CALL synaptic_map_construct (thisno,
     &     num_deepaxax,  num_suppyrRS ,             
     &     map_deepaxax_to_suppyrRS ,   
     &     num_deepaxax_to_suppyrRS ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepaxax,  num_suppyrFRB,             
     &     map_deepaxax_to_suppyrFRB,   
     &     num_deepaxax_to_suppyrFRB,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepaxax,  num_spinstell,             
     &     map_deepaxax_to_spinstell,   
     &     num_deepaxax_to_spinstell,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepaxax,  num_tuftIB   ,             
     &     map_deepaxax_to_tuftIB   ,   
     &     num_deepaxax_to_tuftIB   ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepaxax,  num_tuftRS   ,             
     &     map_deepaxax_to_tuftRS   ,   
     &     num_deepaxax_to_tuftRS   ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepaxax,  num_nontuftRS   ,             
     &     map_deepaxax_to_nontuftRS   ,   
     &     num_deepaxax_to_nontuftRS   ,  display)

          CALL synaptic_map_construct (thisno,
     &     num_deepLTS ,  num_suppyrRS    ,             
     &     map_deepLTS_to_suppyrRS    ,   
     &     num_deepLTS_to_suppyrRS    ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepLTS ,  num_suppyrFRB   ,             
     &     map_deepLTS_to_suppyrFRB   ,   
     &     num_deepLTS_to_suppyrFRB   ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepLTS ,  num_supbask     ,             
     &     map_deepLTS_to_supbask     ,   
     &     num_deepLTS_to_supbask     ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepLTS ,  num_supaxax     ,             
     &     map_deepLTS_to_supaxax     ,   
     &     num_deepLTS_to_supaxax     ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepLTS ,  num_supLTS      ,             
     &     map_deepLTS_to_supLTS      ,   
     &     num_deepLTS_to_supLTS      ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepLTS ,  num_spinstell   ,             
     &     map_deepLTS_to_spinstell   ,   
     &     num_deepLTS_to_spinstell   ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepLTS ,  num_tuftIB      ,             
     &     map_deepLTS_to_tuftIB      ,   
     &     num_deepLTS_to_tuftIB      ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepLTS ,  num_tuftRS      ,             
     &     map_deepLTS_to_tuftRS      ,   
     &     num_deepLTS_to_tuftRS      ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepLTS ,  num_deepbask    ,             
     &     map_deepLTS_to_deepbask    ,   
     &     num_deepLTS_to_deepbask    ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepLTS ,  num_deepaxax    ,             
     &     map_deepLTS_to_deepaxax    ,   
     &     num_deepLTS_to_deepaxax    ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepLTS ,  num_deepLTS     ,             
     &     map_deepLTS_to_deepLTS     ,   
     &     num_deepLTS_to_deepLTS     ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_deepLTS ,  num_nontuftRS   ,             
     &     map_deepLTS_to_nontuftRS   ,   
     &     num_deepLTS_to_nontuftRS   ,  display)

          CALL synaptic_map_construct (thisno,
     &     num_TCR ,  num_suppyrRS    ,             
     &     map_TCR_to_suppyrRS    ,   
     &     num_TCR_to_suppyrRS    ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_TCR ,  num_suppyrFRB   ,             
     &     map_TCR_to_suppyrFRB   ,   
     &     num_TCR_to_suppyrFRB   ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_TCR ,  num_supbask     ,             
     &     map_TCR_to_supbask     ,   
     &     num_TCR_to_supbask     ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_TCR ,  num_supng       ,             
     &     map_TCR_to_supng       ,   
     &     num_TCR_to_supng       ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_TCR ,  num_supaxax     ,             
     &     map_TCR_to_supaxax     ,   
     &     num_TCR_to_supaxax     ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_TCR ,  num_spinstell   ,             
     &     map_TCR_to_spinstell   ,   
     &     num_TCR_to_spinstell   ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_TCR ,  num_tuftIB      ,             
     &     map_TCR_to_tuftIB      ,   
     &     num_TCR_to_tuftIB      ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_TCR ,  num_tuftRS      ,             
     &     map_TCR_to_tuftRS      ,   
     &     num_TCR_to_tuftRS      ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_TCR ,  num_deepbask    ,             
     &     map_TCR_to_deepbask    ,   
     &     num_TCR_to_deepbask    ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_TCR ,  num_deepng      ,             
     &     map_TCR_to_deepng      ,   
     &     num_TCR_to_deepng      ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_TCR ,  num_deepaxax    ,             
     &     map_TCR_to_deepaxax    ,   
     &     num_TCR_to_deepaxax    ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_TCR ,  num_nRT         ,             
     &     map_TCR_to_nRT         ,   
     &     num_TCR_to_nRT         ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_TCR ,  num_nontuftRS   ,             
     &     map_TCR_to_nontuftRS   ,   
     &     num_TCR_to_nontuftRS   ,  display)

          CALL synaptic_map_construct (thisno,
     &     num_nRT ,  num_TCR         ,             
     &     map_nRT_to_TCR         ,   
     &     num_nRT_to_TCR         ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_nRT ,  num_nRT         ,             
     &     map_nRT_to_nRT         ,   
     &     num_nRT_to_nRT         ,  display)

          CALL synaptic_map_construct (thisno,
     &     num_nontuftRS ,  num_suppyrRS    ,             
     &     map_nontuftRS_to_suppyrRS    ,   
     &     num_nontuftRS_to_suppyrRS    ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_nontuftRS ,  num_suppyrFRB   ,             
     &     map_nontuftRS_to_suppyrFRB   ,   
     &     num_nontuftRS_to_suppyrFRB   ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_nontuftRS ,  num_supbask     ,             
     &     map_nontuftRS_to_supbask     ,   
     &     num_nontuftRS_to_supbask     ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_nontuftRS ,  num_supaxax     ,             
     &     map_nontuftRS_to_supaxax     ,   
     &     num_nontuftRS_to_supaxax     ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_nontuftRS ,  num_supLTS      ,             
     &     map_nontuftRS_to_supLTS      ,   
     &     num_nontuftRS_to_supLTS      ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_nontuftRS ,  num_spinstell   ,             
     &     map_nontuftRS_to_spinstell   ,   
     &     num_nontuftRS_to_spinstell   ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_nontuftRS ,  num_tuftIB      ,             
     &     map_nontuftRS_to_tuftIB      ,   
     &     num_nontuftRS_to_tuftIB      ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_nontuftRS ,  num_tuftRS      ,             
     &     map_nontuftRS_to_tuftRS      ,   
     &     num_nontuftRS_to_tuftRS      ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_nontuftRS ,  num_deepbask    ,             
     &     map_nontuftRS_to_deepbask    ,   
     &     num_nontuftRS_to_deepbask    ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_nontuftRS ,  num_deepng      ,             
     &     map_nontuftRS_to_deepng      ,   
     &     num_nontuftRS_to_deepng      ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_nontuftRS ,  num_deepaxax    ,             
     &     map_nontuftRS_to_deepaxax    ,   
     &     num_nontuftRS_to_deepaxax    ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_nontuftRS ,  num_deepLTS     ,             
     &     map_nontuftRS_to_deepLTS     ,   
     &     num_nontuftRS_to_deepLTS     ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_nontuftRS ,  num_TCR         ,             
     &     map_nontuftRS_to_TCR         ,   
     &     num_nontuftRS_to_TCR         ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_nontuftRS ,  num_nRT         ,             
     &     map_nontuftRS_to_nRT         ,   
     &     num_nontuftRS_to_nRT         ,  display)
          CALL synaptic_map_construct (thisno,
     &     num_nontuftRS ,  num_nontuftRS   ,             
     &     map_nontuftRS_to_nontuftRS   ,   
     &     num_nontuftRS_to_nontuftRS   ,  display)
c Finish construction of synaptic connection tables.

c Construct synaptic compartment maps.  
                display = 0

          CALL synaptic_compmap_construct (thisno,
     &     num_suppyrRS, com_suppyrRS_to_suppyrRS,           
     &     num_suppyrRS_to_suppyrRS,
     &  ncompallow_suppyrRS_to_suppyrRS,
     &   compallow_suppyrRS_to_suppyrRS, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_suppyrFRB, com_suppyrRS_to_suppyrFRB,          
     &     num_suppyrRS_to_suppyrFRB,
     &    ncompallow_suppyrRS_to_suppyrFRB,
     &     compallow_suppyrRS_to_suppyrFRB, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supbask  , com_suppyrRS_to_supbask,            
     &     num_suppyrRS_to_supbask,
     &    ncompallow_suppyrRS_to_supbask,  
     &     compallow_suppyrRS_to_supbask,   display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supng    , com_suppyrRS_to_supng  ,            
     &     num_suppyrRS_to_supng  ,
     &    ncompallow_suppyrRS_to_supng  ,  
     &     compallow_suppyrRS_to_supng  ,   display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supaxax  , com_suppyrRS_to_supaxax,            
     &     num_suppyrRS_to_supaxax,  
     &    ncompallow_suppyrRS_to_supaxax,  
     &     compallow_suppyrRS_to_supaxax,   display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supLTS   , com_suppyrRS_to_supLTS,             
     &     num_suppyrRS_to_supLTS,   
     &    ncompallow_suppyrRS_to_supLTS,   
     &     compallow_suppyrRS_to_supLTS,    display)

          CALL synaptic_compmap_construct (thisno,
     &     num_spinstell, com_suppyrRS_to_spinstell,          
     &     num_suppyrRS_to_spinstell,
     &    ncompallow_suppyrRS_to_spinstell,
     &     compallow_suppyrRS_to_spinstell, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftIB   , com_suppyrRS_to_tuftIB   ,          
     &     num_suppyrRS_to_tuftIB   ,
     &    ncompallow_suppyrRS_to_tuftIB   ,
     &     compallow_suppyrRS_to_tuftIB   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftRS   , com_suppyrRS_to_tuftRS   ,          
     &     num_suppyrRS_to_tuftRS   ,
     &    ncompallow_suppyrRS_to_tuftRS   ,
     &     compallow_suppyrRS_to_tuftRS   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepbask , com_suppyrRS_to_deepbask ,          
     &     num_suppyrRS_to_deepbask ,
     &    ncompallow_suppyrRS_to_deepbask ,
     &     compallow_suppyrRS_to_deepbask , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepaxax , com_suppyrRS_to_deepaxax ,          
     &     num_suppyrRS_to_deepaxax ,
     &    ncompallow_suppyrRS_to_deepaxax ,
     &     compallow_suppyrRS_to_deepaxax , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepLTS  , com_suppyrRS_to_deepLTS  ,          
     &     num_suppyrRS_to_deepLTS  ,
     &    ncompallow_suppyrRS_to_deepLTS  ,
     &     compallow_suppyrRS_to_deepLTS  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_nontuftRS, com_suppyrRS_to_nontuftRS,          
     &     num_suppyrRS_to_nontuftRS,
     &    ncompallow_suppyrRS_to_nontuftRS,
     &     compallow_suppyrRS_to_nontuftRS, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_suppyrRS , com_suppyrFRB_to_suppyrRS ,          
     &     num_suppyrFRB_to_suppyrRS ,
     &    ncompallow_suppyrFRB_to_suppyrRS ,
     &     compallow_suppyrFRB_to_suppyrRS , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_suppyrFRB, com_suppyrFRB_to_suppyrFRB,          
     &     num_suppyrFRB_to_suppyrFRB,
     &    ncompallow_suppyrFRB_to_suppyrFRB,
     &     compallow_suppyrFRB_to_suppyrFRB, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supbask  , com_suppyrFRB_to_supbask  ,          
     &     num_suppyrFRB_to_supbask  ,
     &    ncompallow_suppyrFRB_to_supbask  ,
     &     compallow_suppyrFRB_to_supbask  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supng    , com_suppyrFRB_to_supng    ,          
     &     num_suppyrFRB_to_supng    ,
     &    ncompallow_suppyrFRB_to_supng    ,
     &     compallow_suppyrFRB_to_supng    , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supaxax  , com_suppyrFRB_to_supaxax  ,          
     &     num_suppyrFRB_to_supaxax  ,
     &    ncompallow_suppyrFRB_to_supaxax  ,
     &     compallow_suppyrFRB_to_supaxax  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supLTS   , com_suppyrFRB_to_supLTS   ,          
     &     num_suppyrFRB_to_supLTS   ,
     &    ncompallow_suppyrFRB_to_supLTS   ,
     &     compallow_suppyrFRB_to_supLTS   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_spinstell, com_suppyrFRB_to_spinstell,          
     &     num_suppyrFRB_to_spinstell,
     &    ncompallow_suppyrFRB_to_spinstell,
     &     compallow_suppyrFRB_to_spinstell, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftIB   , com_suppyrFRB_to_tuftIB   ,          
     &     num_suppyrFRB_to_tuftIB   ,
     &    ncompallow_suppyrFRB_to_tuftIB   ,
     &     compallow_suppyrFRB_to_tuftIB   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftRS   , com_suppyrFRB_to_tuftRS   ,          
     &     num_suppyrFRB_to_tuftRS   ,
     &    ncompallow_suppyrFRB_to_tuftRS   ,
     &     compallow_suppyrFRB_to_tuftRS   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepbask , com_suppyrFRB_to_deepbask ,          
     &     num_suppyrFRB_to_deepbask ,
     &    ncompallow_suppyrFRB_to_deepbask ,
     &     compallow_suppyrFRB_to_deepbask , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepaxax , com_suppyrFRB_to_deepaxax ,          
     &     num_suppyrFRB_to_deepaxax ,
     &    ncompallow_suppyrFRB_to_deepaxax ,
     &     compallow_suppyrFRB_to_deepaxax , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepLTS  , com_suppyrFRB_to_deepLTS  ,          
     &     num_suppyrFRB_to_deepLTS  ,
     &    ncompallow_suppyrFRB_to_deepLTS  ,
     &     compallow_suppyrFRB_to_deepLTS  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_nontuftRS, com_suppyrFRB_to_nontuftRS,          
     &     num_suppyrFRB_to_nontuftRS,
     &    ncompallow_suppyrFRB_to_nontuftRS,
     &     compallow_suppyrFRB_to_nontuftRS, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_suppyrRS , com_supbask_to_suppyrRS ,          
     &     num_supbask_to_suppyrRS ,
     &    ncompallow_supbask_to_suppyrRS ,
     &     compallow_supbask_to_suppyrRS , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_suppyrFRB, com_supbask_to_suppyrFRB,          
     &     num_supbask_to_suppyrFRB,
     &    ncompallow_supbask_to_suppyrFRB,
     &     compallow_supbask_to_suppyrFRB, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supbask  , com_supbask_to_supbask  ,          
     &     num_supbask_to_supbask  ,
     &    ncompallow_supbask_to_supbask  ,
     &     compallow_supbask_to_supbask  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supng    , com_supbask_to_supng    ,          
     &     num_supbask_to_supng    ,
     &    ncompallow_supbask_to_supng    ,
     &     compallow_supbask_to_supng    , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supaxax  , com_supbask_to_supaxax  ,          
     &     num_supbask_to_supaxax  ,
     &    ncompallow_supbask_to_supaxax  ,
     &     compallow_supbask_to_supaxax  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supLTS   , com_supbask_to_supLTS   ,          
     &     num_supbask_to_supLTS   ,
     &    ncompallow_supbask_to_supLTS   ,
     &     compallow_supbask_to_supLTS   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_spinstell, com_supbask_to_spinstell,          
     &     num_supbask_to_spinstell,
     &    ncompallow_supbask_to_spinstell,
     &     compallow_supbask_to_spinstell, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_suppyrRS , com_supng_to_suppyrRS ,          
     &     num_supng_to_suppyrRS ,
     &    ncompallow_supng_to_suppyrRS ,
     &     compallow_supng_to_suppyrRS , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_suppyrFRB, com_supng_to_suppyrFRB,          
     &     num_supng_to_suppyrFRB,
     &    ncompallow_supng_to_suppyrFRB,
     &     compallow_supng_to_suppyrFRB, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_nontuftRS, com_supng_to_nontuftRS,          
     &     num_supng_to_nontuftRS,
     &    ncompallow_supng_to_nontuftRS,
     &     compallow_supng_to_nontuftRS, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftIB   , com_supng_to_tuftIB   ,          
     &     num_supng_to_tuftIB   ,
     &    ncompallow_supng_to_tuftIB   ,
     &     compallow_supng_to_tuftIB   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftRS   , com_supng_to_tuftRS   ,          
     &     num_supng_to_tuftRS   ,
     &    ncompallow_supng_to_tuftRS   ,
     &     compallow_supng_to_tuftRS   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supng    , com_supng_to_supng    ,          
     &     num_supng_to_supng    ,
     &    ncompallow_supng_to_supng    ,
     &     compallow_supng_to_supng    , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supbask  , com_supng_to_supbask  ,          
     &     num_supng_to_supbask  ,
     &    ncompallow_supng_to_supbask  ,
     &     compallow_supng_to_supbask  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_suppyrRS , com_supaxax_to_suppyrRS ,          
     &     num_supaxax_to_suppyrRS ,
     &    ncompallow_supaxax_to_suppyrRS ,
     &     compallow_supaxax_to_suppyrRS , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_suppyrFRB, com_supaxax_to_suppyrFRB,          
     &     num_supaxax_to_suppyrFRB,
     &    ncompallow_supaxax_to_suppyrFRB,
     &     compallow_supaxax_to_suppyrFRB, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_spinstell, com_supaxax_to_spinstell,          
     &     num_supaxax_to_spinstell,
     &    ncompallow_supaxax_to_spinstell,
     &     compallow_supaxax_to_spinstell, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftIB   , com_supaxax_to_tuftIB   ,          
     &     num_supaxax_to_tuftIB   ,
     &    ncompallow_supaxax_to_tuftIB   ,
     &     compallow_supaxax_to_tuftIB   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftRS   , com_supaxax_to_tuftRS   ,          
     &     num_supaxax_to_tuftRS   ,
     &    ncompallow_supaxax_to_tuftRS   ,
     &     compallow_supaxax_to_tuftRS   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_nontuftRS, com_supaxax_to_nontuftRS,          
     &     num_supaxax_to_nontuftRS,
     &    ncompallow_supaxax_to_nontuftRS,
     &     compallow_supaxax_to_nontuftRS, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_suppyrRS , com_supLTS_to_suppyrRS ,          
     &     num_supLTS_to_suppyrRS ,
     &    ncompallow_supLTS_to_suppyrRS ,
     &     compallow_supLTS_to_suppyrRS , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_suppyrFRB, com_supLTS_to_suppyrFRB,          
     &     num_supLTS_to_suppyrFRB,
     &    ncompallow_supLTS_to_suppyrFRB,
     &     compallow_supLTS_to_suppyrFRB, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supbask  , com_supLTS_to_supbask  ,          
     &     num_supLTS_to_supbask  ,
     &    ncompallow_supLTS_to_supbask  ,
     &     compallow_supLTS_to_supbask  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supaxax  , com_supLTS_to_supaxax  ,          
     &     num_supLTS_to_supaxax  ,
     &    ncompallow_supLTS_to_supaxax  ,
     &     compallow_supLTS_to_supaxax  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supLTS   , com_supLTS_to_supLTS   ,          
     &     num_supLTS_to_supLTS   ,
     &    ncompallow_supLTS_to_supLTS   ,
     &     compallow_supLTS_to_supLTS   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_spinstell, com_supLTS_to_spinstell,          
     &     num_supLTS_to_spinstell,
     &    ncompallow_supLTS_to_spinstell,
     &     compallow_supLTS_to_spinstell, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftIB   , com_supLTS_to_tuftIB   ,          
     &     num_supLTS_to_tuftIB   ,
     &    ncompallow_supLTS_to_tuftIB   ,
     &     compallow_supLTS_to_tuftIB   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftRS   , com_supLTS_to_tuftRS   ,          
     &     num_supLTS_to_tuftRS   ,
     &    ncompallow_supLTS_to_tuftRS   ,
     &     compallow_supLTS_to_tuftRS   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepbask , com_supLTS_to_deepbask ,          
     &     num_supLTS_to_deepbask ,
     &    ncompallow_supLTS_to_deepbask ,
     &     compallow_supLTS_to_deepbask , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepaxax , com_supLTS_to_deepaxax ,          
     &     num_supLTS_to_deepaxax ,
     &    ncompallow_supLTS_to_deepaxax ,
     &     compallow_supLTS_to_deepaxax , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepLTS  , com_supLTS_to_deepLTS  ,          
     &     num_supLTS_to_deepLTS  ,
     &    ncompallow_supLTS_to_deepLTS  ,
     &     compallow_supLTS_to_deepLTS  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_nontuftRS, com_supLTS_to_nontuftRS,          
     &     num_supLTS_to_nontuftRS,
     &    ncompallow_supLTS_to_nontuftRS,
     &     compallow_supLTS_to_nontuftRS, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_suppyrRS , com_spinstell_to_suppyrRS ,          
     &     num_spinstell_to_suppyrRS ,
     &    ncompallow_spinstell_to_suppyrRS ,
     &     compallow_spinstell_to_suppyrRS , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_suppyrFRB, com_spinstell_to_suppyrFRB,          
     &     num_spinstell_to_suppyrFRB,
     &    ncompallow_spinstell_to_suppyrFRB,
     &     compallow_spinstell_to_suppyrFRB, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supbask  , com_spinstell_to_supbask  ,          
     &     num_spinstell_to_supbask  ,
     &    ncompallow_spinstell_to_supbask  ,
     &     compallow_spinstell_to_supbask  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supaxax  , com_spinstell_to_supaxax  ,          
     &     num_spinstell_to_supaxax  ,
     &    ncompallow_spinstell_to_supaxax  ,
     &     compallow_spinstell_to_supaxax  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supLTS   , com_spinstell_to_supLTS   ,          
     &     num_spinstell_to_supLTS   ,
     &    ncompallow_spinstell_to_supLTS   ,
     &     compallow_spinstell_to_supLTS   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_spinstell, com_spinstell_to_spinstell,          
     &     num_spinstell_to_spinstell,
     &    ncompallow_spinstell_to_spinstell,
     &     compallow_spinstell_to_spinstell, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftIB   , com_spinstell_to_tuftIB   ,          
     &     num_spinstell_to_tuftIB   ,
     &    ncompallow_spinstell_to_tuftIB   ,
     &     compallow_spinstell_to_tuftIB   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftRS   , com_spinstell_to_tuftRS   ,          
     &     num_spinstell_to_tuftRS   ,
     &    ncompallow_spinstell_to_tuftRS   ,
     &     compallow_spinstell_to_tuftRS   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepbask , com_spinstell_to_deepbask ,          
     &     num_spinstell_to_deepbask ,
     &    ncompallow_spinstell_to_deepbask ,
     &     compallow_spinstell_to_deepbask , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepng   , com_spinstell_to_deepng   ,          
     &     num_spinstell_to_deepng   ,
     &    ncompallow_spinstell_to_deepng   ,
     &     compallow_spinstell_to_deepng   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepaxax , com_spinstell_to_deepaxax ,          
     &     num_spinstell_to_deepaxax ,
     &    ncompallow_spinstell_to_deepaxax ,
     &     compallow_spinstell_to_deepaxax , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepLTS  , com_spinstell_to_deepLTS  ,          
     &     num_spinstell_to_deepLTS  ,
     &    ncompallow_spinstell_to_deepLTS  ,
     &     compallow_spinstell_to_deepLTS  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_nontuftRS, com_spinstell_to_nontuftRS,          
     &     num_spinstell_to_nontuftRS,
     &    ncompallow_spinstell_to_nontuftRS,
     &     compallow_spinstell_to_nontuftRS, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_suppyrRS , com_tuftIB_to_suppyrRS ,          
     &     num_tuftIB_to_suppyrRS ,
     &    ncompallow_tuftIB_to_suppyrRS ,
     &     compallow_tuftIB_to_suppyrRS , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_suppyrFRB, com_tuftIB_to_suppyrFRB,          
     &     num_tuftIB_to_suppyrFRB,
     &    ncompallow_tuftIB_to_suppyrFRB,
     &     compallow_tuftIB_to_suppyrFRB, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supbask  , com_tuftIB_to_supbask  ,          
     &     num_tuftIB_to_supbask  ,
     &    ncompallow_tuftIB_to_supbask  ,
     &     compallow_tuftIB_to_supbask  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supaxax  , com_tuftIB_to_supaxax  ,          
     &     num_tuftIB_to_supaxax  ,
     &    ncompallow_tuftIB_to_supaxax  ,
     &     compallow_tuftIB_to_supaxax  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supLTS   , com_tuftIB_to_supLTS   ,          
     &     num_tuftIB_to_supLTS   ,
     &    ncompallow_tuftIB_to_supLTS   ,
     &     compallow_tuftIB_to_supLTS   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_spinstell, com_tuftIB_to_spinstell,          
     &     num_tuftIB_to_spinstell,
     &    ncompallow_tuftIB_to_spinstell,
     &     compallow_tuftIB_to_spinstell, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftIB   , com_tuftIB_to_tuftIB   ,          
     &     num_tuftIB_to_tuftIB   ,
     &    ncompallow_tuftIB_to_tuftIB   ,
     &     compallow_tuftIB_to_tuftIB   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftRS   , com_tuftIB_to_tuftRS   ,          
     &     num_tuftIB_to_tuftRS   ,
     &    ncompallow_tuftIB_to_tuftRS   ,
     &     compallow_tuftIB_to_tuftRS   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepbask , com_tuftIB_to_deepbask ,          
     &     num_tuftIB_to_deepbask ,
     &    ncompallow_tuftIB_to_deepbask ,
     &     compallow_tuftIB_to_deepbask , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepng   , com_tuftIB_to_deepng   ,          
     &     num_tuftIB_to_deepng   ,
     &    ncompallow_tuftIB_to_deepng   ,
     &     compallow_tuftIB_to_deepng   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepaxax , com_tuftIB_to_deepaxax ,          
     &     num_tuftIB_to_deepaxax ,
     &    ncompallow_tuftIB_to_deepaxax ,
     &     compallow_tuftIB_to_deepaxax , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepLTS  , com_tuftIB_to_deepLTS  ,          
     &     num_tuftIB_to_deepLTS  ,
     &    ncompallow_tuftIB_to_deepLTS  ,
     &     compallow_tuftIB_to_deepLTS  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_nontuftRS, com_tuftIB_to_nontuftRS,          
     &     num_tuftIB_to_nontuftRS,
     &    ncompallow_tuftIB_to_nontuftRS,
     &     compallow_tuftIB_to_nontuftRS, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_suppyrRS , com_tuftRS_to_suppyrRS ,          
     &     num_tuftRS_to_suppyrRS ,
     &    ncompallow_tuftRS_to_suppyrRS ,
     &     compallow_tuftRS_to_suppyrRS , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_suppyrFRB, com_tuftRS_to_suppyrFRB,          
     &     num_tuftRS_to_suppyrFRB,
     &    ncompallow_tuftRS_to_suppyrFRB,
     &     compallow_tuftRS_to_suppyrFRB, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supbask  , com_tuftRS_to_supbask  ,          
     &     num_tuftRS_to_supbask  ,
     &    ncompallow_tuftRS_to_supbask  ,
     &     compallow_tuftRS_to_supbask  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supaxax  , com_tuftRS_to_supaxax  ,          
     &     num_tuftRS_to_supaxax  ,
     &    ncompallow_tuftRS_to_supaxax  ,
     &     compallow_tuftRS_to_supaxax  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supLTS   , com_tuftRS_to_supLTS   ,          
     &     num_tuftRS_to_supLTS   ,
     &    ncompallow_tuftRS_to_supLTS   ,
     &     compallow_tuftRS_to_supLTS   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_spinstell, com_tuftRS_to_spinstell,          
     &     num_tuftRS_to_spinstell,
     &    ncompallow_tuftRS_to_spinstell,
     &     compallow_tuftRS_to_spinstell, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftIB   , com_tuftRS_to_tuftIB   ,          
     &     num_tuftRS_to_tuftIB   ,
     &    ncompallow_tuftRS_to_tuftIB   ,
     &     compallow_tuftRS_to_tuftIB   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftRS   , com_tuftRS_to_tuftRS   ,          
     &     num_tuftRS_to_tuftRS   ,
     &    ncompallow_tuftRS_to_tuftRS   ,
     &     compallow_tuftRS_to_tuftRS   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepbask , com_tuftRS_to_deepbask ,          
     &     num_tuftRS_to_deepbask ,
     &    ncompallow_tuftRS_to_deepbask ,
     &     compallow_tuftRS_to_deepbask , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepng   , com_tuftRS_to_deepng   ,          
     &     num_tuftRS_to_deepng   ,
     &    ncompallow_tuftRS_to_deepng   ,
     &     compallow_tuftRS_to_deepng   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepaxax , com_tuftRS_to_deepaxax ,          
     &     num_tuftRS_to_deepaxax ,
     &    ncompallow_tuftRS_to_deepaxax ,
     &     compallow_tuftRS_to_deepaxax , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepLTS  , com_tuftRS_to_deepLTS  ,          
     &     num_tuftRS_to_deepLTS  ,
     &    ncompallow_tuftRS_to_deepLTS  ,
     &     compallow_tuftRS_to_deepLTS  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_nontuftRS, com_tuftRS_to_nontuftRS,          
     &     num_tuftRS_to_nontuftRS,
     &    ncompallow_tuftRS_to_nontuftRS,
     &     compallow_tuftRS_to_nontuftRS, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_spinstell, com_deepbask_to_spinstell,          
     &     num_deepbask_to_spinstell,
     &    ncompallow_deepbask_to_spinstell,
     &     compallow_deepbask_to_spinstell, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftIB   , com_deepbask_to_tuftIB   ,          
     &     num_deepbask_to_tuftIB   ,
     &    ncompallow_deepbask_to_tuftIB   ,
     &     compallow_deepbask_to_tuftIB   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftRS   , com_deepbask_to_tuftRS   ,          
     &     num_deepbask_to_tuftRS   ,
     &    ncompallow_deepbask_to_tuftRS   ,
     &     compallow_deepbask_to_tuftRS   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepbask , com_deepbask_to_deepbask ,          
     &     num_deepbask_to_deepbask ,
     &    ncompallow_deepbask_to_deepbask ,
     &     compallow_deepbask_to_deepbask , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepng   , com_deepbask_to_deepng   ,          
     &     num_deepbask_to_deepng   ,
     &    ncompallow_deepbask_to_deepng   ,
     &     compallow_deepbask_to_deepng   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepaxax , com_deepbask_to_deepaxax ,          
     &     num_deepbask_to_deepaxax ,
     &    ncompallow_deepbask_to_deepaxax ,
     &     compallow_deepbask_to_deepaxax , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepLTS  , com_deepbask_to_deepLTS  ,          
     &     num_deepbask_to_deepLTS  ,
     &    ncompallow_deepbask_to_deepLTS  ,
     &     compallow_deepbask_to_deepLTS  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_nontuftRS, com_deepbask_to_nontuftRS,          
     &     num_deepbask_to_nontuftRS,
     &    ncompallow_deepbask_to_nontuftRS,
     &     compallow_deepbask_to_nontuftRS, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftIB   , com_deepng_to_tuftIB   ,          
     &     num_deepng_to_tuftIB   ,
     &    ncompallow_deepng_to_tuftIB   ,
     &     compallow_deepng_to_tuftIB   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftRS   , com_deepng_to_tuftRS   ,          
     &     num_deepng_to_tuftRS   ,
     &    ncompallow_deepng_to_tuftRS   ,
     &     compallow_deepng_to_tuftRS   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_nontuftRS, com_deepng_to_nontuftRS,          
     &     num_deepng_to_nontuftRS,
     &    ncompallow_deepng_to_nontuftRS,
     &     compallow_deepng_to_nontuftRS, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_spinstell, com_deepng_to_spinstell,          
     &     num_deepng_to_spinstell,
     &    ncompallow_deepng_to_spinstell,
     &     compallow_deepng_to_spinstell, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepng   , com_deepng_to_deepng   ,          
     &     num_deepng_to_deepng   ,
     &    ncompallow_deepng_to_deepng   ,
     &     compallow_deepng_to_deepng   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepbask , com_deepng_to_deepbask ,          
     &     num_deepng_to_deepbask ,
     &    ncompallow_deepng_to_deepbask ,
     &     compallow_deepng_to_deepbask , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_suppyrRS , com_deepaxax_to_suppyrRS ,          
     &     num_deepaxax_to_suppyrRS ,
     &    ncompallow_deepaxax_to_suppyrRS ,
     &     compallow_deepaxax_to_suppyrRS , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_suppyrFRB, com_deepaxax_to_suppyrFRB,          
     &     num_deepaxax_to_suppyrFRB,
     &    ncompallow_deepaxax_to_suppyrFRB,
     &     compallow_deepaxax_to_suppyrFRB, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_spinstell, com_deepaxax_to_spinstell,          
     &     num_deepaxax_to_spinstell,
     &    ncompallow_deepaxax_to_spinstell,
     &     compallow_deepaxax_to_spinstell, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftIB   , com_deepaxax_to_tuftIB   ,          
     &     num_deepaxax_to_tuftIB   ,
     &    ncompallow_deepaxax_to_tuftIB   ,
     &     compallow_deepaxax_to_tuftIB   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftRS   , com_deepaxax_to_tuftRS   ,          
     &     num_deepaxax_to_tuftRS   ,
     &    ncompallow_deepaxax_to_tuftRS   ,
     &     compallow_deepaxax_to_tuftRS   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_nontuftRS, com_deepaxax_to_nontuftRS,          
     &     num_deepaxax_to_nontuftRS,
     &    ncompallow_deepaxax_to_nontuftRS,
     &     compallow_deepaxax_to_nontuftRS, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_suppyrRS , com_deepLTS_to_suppyrRS ,          
     &     num_deepLTS_to_suppyrRS ,
     &    ncompallow_deepLTS_to_suppyrRS ,
     &     compallow_deepLTS_to_suppyrRS , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_suppyrFRB, com_deepLTS_to_suppyrFRB,          
     &     num_deepLTS_to_suppyrFRB,
     &    ncompallow_deepLTS_to_suppyrFRB,
     &     compallow_deepLTS_to_suppyrFRB, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supbask  , com_deepLTS_to_supbask  ,          
     &     num_deepLTS_to_supbask  ,
     &    ncompallow_deepLTS_to_supbask  ,
     &     compallow_deepLTS_to_supbask  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supaxax  , com_deepLTS_to_supaxax  ,          
     &     num_deepLTS_to_supaxax  ,
     &    ncompallow_deepLTS_to_supaxax  ,
     &     compallow_deepLTS_to_supaxax  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supLTS   , com_deepLTS_to_supLTS   ,          
     &     num_deepLTS_to_supLTS   ,
     &    ncompallow_deepLTS_to_supLTS   ,
     &     compallow_deepLTS_to_supLTS   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_spinstell, com_deepLTS_to_spinstell,          
     &     num_deepLTS_to_spinstell,
     &    ncompallow_deepLTS_to_spinstell,
     &     compallow_deepLTS_to_spinstell, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftIB   , com_deepLTS_to_tuftIB   ,          
     &     num_deepLTS_to_tuftIB   ,
     &    ncompallow_deepLTS_to_tuftIB   ,
     &     compallow_deepLTS_to_tuftIB   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftRS   , com_deepLTS_to_tuftRS   ,          
     &     num_deepLTS_to_tuftRS   ,
     &    ncompallow_deepLTS_to_tuftRS   ,
     &     compallow_deepLTS_to_tuftRS   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepbask , com_deepLTS_to_deepbask ,          
     &     num_deepLTS_to_deepbask ,
     &    ncompallow_deepLTS_to_deepbask ,
     &     compallow_deepLTS_to_deepbask , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepaxax , com_deepLTS_to_deepaxax ,          
     &     num_deepLTS_to_deepaxax ,
     &    ncompallow_deepLTS_to_deepaxax ,
     &     compallow_deepLTS_to_deepaxax , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepLTS  , com_deepLTS_to_deepLTS  ,          
     &     num_deepLTS_to_deepLTS  ,
     &    ncompallow_deepLTS_to_deepLTS  ,
     &     compallow_deepLTS_to_deepLTS  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_nontuftRS, com_deepLTS_to_nontuftRS,          
     &     num_deepLTS_to_nontuftRS,
     &    ncompallow_deepLTS_to_nontuftRS,
     &     compallow_deepLTS_to_nontuftRS, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_suppyrRS , com_TCR_to_suppyrRS ,          
     &     num_TCR_to_suppyrRS ,
     &    ncompallow_TCR_to_suppyrRS ,
     &     compallow_TCR_to_suppyrRS , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_suppyrFRB, com_TCR_to_suppyrFRB,          
     &     num_TCR_to_suppyrFRB,
     &    ncompallow_TCR_to_suppyrFRB,
     &     compallow_TCR_to_suppyrFRB, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supbask  , com_TCR_to_supbask  ,          
     &     num_TCR_to_supbask  ,
     &    ncompallow_TCR_to_supbask  ,
     &     compallow_TCR_to_supbask  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supng    , com_TCR_to_supng    ,          
     &     num_TCR_to_supng    ,
     &    ncompallow_TCR_to_supng    ,
     &     compallow_TCR_to_supng    , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supaxax  , com_TCR_to_supaxax  ,          
     &     num_TCR_to_supaxax  ,
     &    ncompallow_TCR_to_supaxax  ,
     &     compallow_TCR_to_supaxax  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_spinstell, com_TCR_to_spinstell,          
     &     num_TCR_to_spinstell,
     &    ncompallow_TCR_to_spinstell,
     &     compallow_TCR_to_spinstell, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftIB   , com_TCR_to_tuftIB   ,          
     &     num_TCR_to_tuftIB   ,
     &    ncompallow_TCR_to_tuftIB   ,
     &     compallow_TCR_to_tuftIB   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftRS   , com_TCR_to_tuftRS   ,          
     &     num_TCR_to_tuftRS   ,
     &    ncompallow_TCR_to_tuftRS   ,
     &     compallow_TCR_to_tuftRS   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepbask , com_TCR_to_deepbask ,          
     &     num_TCR_to_deepbask ,
     &    ncompallow_TCR_to_deepbask ,
     &     compallow_TCR_to_deepbask , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepng   , com_TCR_to_deepng   ,          
     &     num_TCR_to_deepng   ,
     &    ncompallow_TCR_to_deepng   ,
     &     compallow_TCR_to_deepng   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepaxax , com_TCR_to_deepaxax ,          
     &     num_TCR_to_deepaxax ,
     &    ncompallow_TCR_to_deepaxax ,
     &     compallow_TCR_to_deepaxax , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_nRT      , com_TCR_to_nRT      ,          
     &     num_TCR_to_nRT      ,
     &    ncompallow_TCR_to_nRT      ,
     &     compallow_TCR_to_nRT      , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_nontuftRS, com_TCR_to_nontuftRS,          
     &     num_TCR_to_nontuftRS,
     &    ncompallow_TCR_to_nontuftRS,
     &     compallow_TCR_to_nontuftRS, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_TCR      , com_nRT_to_TCR      ,          
     &     num_nRT_to_TCR      ,
     &    ncompallow_nRT_to_TCR      ,
     &     compallow_nRT_to_TCR      , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_nRT      , com_nRT_to_nRT      ,          
     &     num_nRT_to_nRT      ,
     &    ncompallow_nRT_to_nRT      ,
     &     compallow_nRT_to_nRT      , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_suppyrRS , com_nontuftRS_to_suppyrRS ,          
     &     num_nontuftRS_to_suppyrRS ,
     &    ncompallow_nontuftRS_to_suppyrRS ,
     &     compallow_nontuftRS_to_suppyrRS , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_suppyrFRB, com_nontuftRS_to_suppyrFRB,          
     &     num_nontuftRS_to_suppyrFRB,
     &    ncompallow_nontuftRS_to_suppyrFRB,
     &     compallow_nontuftRS_to_suppyrFRB, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supbask  , com_nontuftRS_to_supbask  ,          
     &     num_nontuftRS_to_supbask  ,
     &    ncompallow_nontuftRS_to_supbask  ,
     &     compallow_nontuftRS_to_supbask  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supaxax  , com_nontuftRS_to_supaxax  ,          
     &     num_nontuftRS_to_supaxax  ,
     &    ncompallow_nontuftRS_to_supaxax  ,
     &     compallow_nontuftRS_to_supaxax  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_supLTS   , com_nontuftRS_to_supLTS   ,          
     &     num_nontuftRS_to_supLTS   ,
     &    ncompallow_nontuftRS_to_supLTS   ,
     &     compallow_nontuftRS_to_supLTS   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_spinstell, com_nontuftRS_to_spinstell,          
     &     num_nontuftRS_to_spinstell,
     &    ncompallow_nontuftRS_to_spinstell,
     &     compallow_nontuftRS_to_spinstell, display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftIB   , com_nontuftRS_to_tuftIB   ,          
     &     num_nontuftRS_to_tuftIB   ,
     &    ncompallow_nontuftRS_to_tuftIB   ,
     &     compallow_nontuftRS_to_tuftIB   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_tuftRS   , com_nontuftRS_to_tuftRS   ,          
     &     num_nontuftRS_to_tuftRS   ,
     &    ncompallow_nontuftRS_to_tuftRS   ,
     &     compallow_nontuftRS_to_tuftRS   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepbask , com_nontuftRS_to_deepbask ,          
     &     num_nontuftRS_to_deepbask ,
     &    ncompallow_nontuftRS_to_deepbask ,
     &     compallow_nontuftRS_to_deepbask , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepng   , com_nontuftRS_to_deepng   ,          
     &     num_nontuftRS_to_deepng   ,
     &    ncompallow_nontuftRS_to_deepng   ,
     &     compallow_nontuftRS_to_deepng   , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepaxax , com_nontuftRS_to_deepaxax ,          
     &     num_nontuftRS_to_deepaxax ,
     &    ncompallow_nontuftRS_to_deepaxax ,
     &     compallow_nontuftRS_to_deepaxax , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_deepLTS  , com_nontuftRS_to_deepLTS  ,          
     &     num_nontuftRS_to_deepLTS  ,
     &    ncompallow_nontuftRS_to_deepLTS  ,
     &     compallow_nontuftRS_to_deepLTS  , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_TCR      , com_nontuftRS_to_TCR      ,          
     &     num_nontuftRS_to_TCR      ,
     &    ncompallow_nontuftRS_to_TCR      ,
     &     compallow_nontuftRS_to_TCR      , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_nRT      , com_nontuftRS_to_nRT      ,          
     &     num_nontuftRS_to_nRT      ,
     &    ncompallow_nontuftRS_to_nRT      ,
     &     compallow_nontuftRS_to_nRT      , display)

          CALL synaptic_compmap_construct (thisno,
     &     num_nontuftRS, com_nontuftRS_to_nontuftRS,          
     &     num_nontuftRS_to_nontuftRS,
     &    ncompallow_nontuftRS_to_nontuftRS,
     &     compallow_nontuftRS_to_nontuftRS, display)

c Finish construction of synaptic compartment maps. 

c Display TCR-to-spinstell connectivity: input cell, compartment
c        write(6,988)
988      format('  TCR to spinstell connectivity')
         do i = 1, num_spinstell
c          write(6,989) i
989        format(' spinstell number ',i4)
           do j = 1, num_TCR_to_spinstell
c           write(6,990) j, map_TCR_to_spinstell(j,i),
c    &             com_TCR_to_spinstell(j,i)
990         format(i5,i5,i5)
           end do
          end do


c Construct gap-junction tables
! axax interneurons a special case
           gjtable_supaxax(1,1) = 1
           gjtable_supaxax(1,2) = 12
           gjtable_supaxax(1,3) = 2
           gjtable_supaxax(1,4) = 12
           gjtable_deepaxax(1,1) = 1
           gjtable_deepaxax(1,2) = 12
           gjtable_deepaxax(1,3) = 2
           gjtable_deepaxax(1,4) = 12

      CALL groucho_gapbld (thisno, num_suppyrRS,
     & totaxgj_suppyrRS  , gjtable_suppyrRS,
     & table_axgjcompallow_suppyrRS, 
     & num_axgjcompallow_suppyrRS, 0) 

      CALL groucho_gapbld (thisno, num_suppyrFRB,
     & totaxgj_suppyrFRB , gjtable_suppyrFRB,
     & table_axgjcompallow_suppyrFRB,
     & num_axgjcompallow_suppyrFRB,  0) 

      call GROUCHO_gapbld_mix (thisno, num_suppyrRS,        
     & num_suppyrFRB, totaxgj_suppyr, gjtable_suppyr,
     & table_axgjcompallow_suppyrRS,
     & num_axgjcompallow_suppyrRS, 0)
      
      CALL groucho_gapbld (thisno, num_spinstell,
     & totaxgj_spinstell , gjtable_spinstell,
     & table_axgjcompallow_spinstell,
     & num_axgjcompallow_spinstell,  0) 

      CALL groucho_gapbld (thisno, num_tuftIB,   
     & totaxgj_tuftIB    , gjtable_tuftIB   ,
     & table_axgjcompallow_tuftIB   ,
     & num_axgjcompallow_tuftIB   ,  0) 

      CALL groucho_gapbld (thisno, num_tuftRS,   
     & totaxgj_tuftRS    , gjtable_tuftRS   ,
     & table_axgjcompallow_tuftRS   ,
     & num_axgjcompallow_tuftRS   ,  0) 

      call GROUCHO_gapbld_mix (thisno, num_tuftIB,        
     & num_tuftRS, totaxgj_tuft, gjtable_tuft,
     & table_axgjcompallow_tuftIB,
     & num_axgjcompallow_tuftIB, 0)
      
      CALL groucho_gapbld (thisno, num_nontuftRS,   
     & totaxgj_nontuftRS    , gjtable_nontuftRS   ,
     & table_axgjcompallow_nontuftRS   ,
     & num_axgjcompallow_nontuftRS   ,  0) 

      CALL groucho_gapbld (thisno, num_supbask  ,   
     & totSDgj_supbask      , gjtable_supbask     ,
     & table_SDgjcompallow_supbask     ,
     & num_SDgjcompallow_supbask     ,  0) 

      CALL groucho_gapbld (thisno, num_supng    ,   
     & totSDgj_supng        , gjtable_supng       ,
     & table_SDgjcompallow_supng       ,
     & num_SDgjcompallow_supng       ,  0) 

      CALL groucho_gapbld (thisno, num_supLTS   ,   
     & totSDgj_supLTS       , gjtable_supLTS      ,
     & table_SDgjcompallow_supLTS      ,
     & num_SDgjcompallow_supLTS      ,  0) 

      CALL groucho_gapbld (thisno, num_deepbask ,   
     & totSDgj_deepbask     , gjtable_deepbask    ,
     & table_SDgjcompallow_deepbask    ,
     & num_SDgjcompallow_deepbask    ,  0) 

      CALL groucho_gapbld (thisno, num_deepng   ,   
     & totSDgj_deepng       , gjtable_deepng      ,
     & table_SDgjcompallow_deepng      ,
     & num_SDgjcompallow_deepng      ,  0) 

      CALL groucho_gapbld (thisno, num_deepLTS  ,   
     & totSDgj_deepLTS      , gjtable_deepLTS     ,
     & table_SDgjcompallow_deepLTS     ,
     & num_SDgjcompallow_deepLTS     ,  0) 

      CALL groucho_gapbld (thisno, num_TCR      ,   
     & totaxgj_TCR          , gjtable_TCR         ,
     & table_axgjcompallow_TCR         ,
     & num_axgjcompallow_TCR         ,  0) 

      CALL groucho_gapbld (thisno, num_nRT      ,   
     & totSDgj_nRT          , gjtable_nRT         ,
     & table_SDgjcompallow_nRT         ,
     & num_SDgjcompallow_nRT         ,  0) 

! Define spread of values for gGABA_nRT_to_TCR
       call durand(seed,num_nRT,ranvec_nRT)
       do L = 1, num_nRT
        gGABA_nRT_to_TCR(L) = 0.7d-3 + 1.4d-3 * ranvec_nRT(L)
       end do

! Define tonic currents to different cell types
       call durand(seed,num_suppyrRS ,ranvec_suppyrRS )
       do L = 1, num_suppyrRS 
       do i = 69, 74  ! axonal compartments
c       curr_suppyrRS  (1,L) = -0.025d0 + 0.05d0 *
c       curr_suppyrRS  (i,L) =  0.050d0 + 0.005d0 *
        curr_suppyrRS  (1,L) =  0.50d0 + 0.05d0 *
     &    ranvec_suppyrRS (L)
       end do
       end do
       curr_suppyrRS (1,4) = 0.15d0  ! DEPOLARIZE 1 CELL

       call durand(seed,num_suppyrFRB,ranvec_suppyrFRB)
       do L = 1, num_suppyrFRB
       do i = 69, 74  ! axonal compartments
        curr_suppyrFRB (i,L) = 0.250d0 + 0.005d0 *
c       curr_suppyrFRB (1,L) = -0.500d0 + 0.05d0 *
     &    ranvec_suppyrFRB(L)
       end do
       end do

       call durand(seed,num_supbask  ,ranvec_supbask  )
       do L = 1, num_supbask    
c       curr_supbask   (1,L) = -0.10d0 + 0.02d0 *
        curr_supbask   (1,L) = -0.01d0 + 0.02d0 *
     &    ranvec_supbask  (L)
       end do

       call durand(seed,num_deepbask  ,ranvec_deepbask  )
       do L = 1, num_deepbask    
        curr_deepbask   (1,L) = -0.10d0 + 0.02d0 *
     &    ranvec_deepbask  (L)
       end do

       do L = 1, num_supng
          curr_supng (1,L) = -0.03d0 ! to suppress spontaneous firing
       end do

       call durand(seed,num_spinstell,ranvec_spinstell)
       do L = 1, num_spinstell  
c       curr_spinstell (1,L) = -0.10d0 + 0.05d0 *
c       curr_spinstell (1,L) = -0.25d0 + 0.05d0 *
        curr_spinstell (1,L) =  0.00d0 + 0.05d0 *
     &    ranvec_spinstell(L)
       end do

       call durand(seed,num_tuftIB   ,ranvec_tuftIB   )
       do L = 1, num_tuftIB    
!       curr_tuftIB    (1,L) = 0.10d0 + 0.1d0 *
!       curr_tuftIB    (1,L) = 0.00d0 + 0.1d0 *
!       curr_tuftIB    (1,L) = -1.00d0 + 0.1d0 * ! ? suppress intrinsic bursting
!       curr_tuftIB    (1,L) = 1.00d0 + 0.1d0 *  !  ? wake up cortex ?
!       curr_tuftIB    (1,L) = 1.50d0 + 0.1d0 *  !  ? REALLY wake up cortex ?
          do i = 2, 34
c       curr_tuftIB    (i,L) = 0.00d0 + 0.040d0 *  ! current to basal/oblique dendrites 
c       curr_tuftIB    (i,L) =-0.02d0 + 0.040d0 *  ! current to basal/oblique dendrites 
! -0.02 + 0.04...  used in interactB5
c       curr_tuftIB    (i,L) =-0.01d0 + 0.01d0 *  ! current to basal/oblique dendrites 
        curr_tuftIB    (i,L) = 0.020d0 + 0.01d0 *  ! current to basal/oblique dendrites 
     &    ranvec_tuftIB   (L)
          end do
        curr_tuftIB (57,L) = -0.015d0 ! axon
        curr_tuftIB (58,L) = -0.015d0 ! axon
        curr_tuftIB (59,L) = -0.015d0 ! axon
        curr_tuftIB (60,L) = -0.015d0 ! axon
        curr_tuftIB (61,L) = -0.015d0 ! axon
       end do

       call durand(seed,num_tuftRS   ,ranvec_tuftRS   )
       do L = 1, num_tuftRS    
!       curr_tuftRS    (1,L) = 0.10d0 + 0.1d0 *
!       curr_tuftRS    (1,L) = 0.00d0 + 0.1d0 *
!       curr_tuftRS    (1,L) = 1.00d0 + 0.1d0 *  !  ? wake up cortex?
          do i = 2, 34
        curr_tuftRS    (i,L) = -0.05d0 + 0.01d0 *  ! current to basal/oblique dendrites 
     &    ranvec_tuftRS   (L)
          end do
        curr_tuftRS (57,L) = -0.04d0 ! axon
        curr_tuftRS (58,L) = -0.04d0 ! axon
        curr_tuftRS (59,L) = -0.04d0 ! axon
        curr_tuftRS (60,L) = -0.04d0 ! axon
        curr_tuftRS (61,L) = -0.04d0 ! axon
       end do

       do L = 1, num_supng
          curr_supng (1,L) = -0.03d0 ! to suppress spontaneous firing
       end do

       do L = 1, num_deepng
c         curr_deepng (1,L) = -0.03d0 ! to suppress spontaneous firing
c         curr_deepng (1,L) = -0.025d0 ! to suppress spontaneous firing
          curr_deepng (1,L) = -0.045d0 ! to suppress spontaneous firing
c         curr_deepng (1,L) = -0.06d0 ! increase the hyperpol. curr for delta90
       end do

       call durand(seed,num_nontuftRS ,ranvec_nontuftRS )
       do L = 1, num_nontuftRS    
          if (L.le.(num_nontuftRS - nontuftRS_nFRB)) then
             z = 0.60d0
!            z = 0.50d0
          else
c            z = 0.0d0 ! 27 Jan 2005
!            z = 0.4d0
             z = 1.0d0
          endif
c       curr_nontuftRS  (1,L) = z + 0.1d0 *
c       curr_nontuftRS  (1,L) = z - 0.4d0 * ! decrease spont. firing
        curr_nontuftRS  (1,L) = z - 0.2d0 * ! decrease spont. firing
!       curr_nontuftRS  (1,L) = 0.75d0 + 0.1d0 *  ! ? wake up cortex
     &    ranvec_nontuftRS (L)
       end do

       call durand(seed,num_nRT       ,ranvec_nRT       )
       do L = 1, num_nRT          
        curr_nRT        (1,L) = -0.05d0 + 0.05d0 *
     &    ranvec_nRT       (L)
c        if (thisno.eq.0) then
c        write(6,8782) L, curr_nRT(1,L)
c        endif
8782     format(i4,3x,f8.3)
       end do

! During sz, curr to TCR can be zero
       call durand(seed,num_TCR       ,ranvec_TCR       )
       do L = 1, num_TCR          
!       curr_TCR        (1,L) = 1.40d0 + 0.01d0 *
        curr_TCR        (1,L) = 0.00d0 + 0.01d0 *
     &    ranvec_TCR       (L)
       end do

! ? remove from the picture layers 2/3 and 4, by hyperpolarizing the respective axons
           go to 9901
             do L = 1, num_suppyrRS
              curr_suppyrRS(numcomp_suppyrRS,L) = -0.25d0
             end do

             do L = 1, num_suppyrFRB
              curr_suppyrFRB(numcomp_suppyrFRB,L) = -0.25d0
             end do

             do L = 1, num_supbask  
              curr_supbask  (numcomp_supbask  ,L) = -0.25d0
             end do

             do L = 1, num_supng    
              curr_supng    (numcomp_supng    ,L) = -0.25d0
             end do

             do L = 1, num_supaxax  
              curr_supaxax  (numcomp_supaxax  ,L) = -0.25d0
             end do

             do L = 1, num_supLTS   
              curr_supLTS   (numcomp_supLTS   ,L) = -0.25d0
             end do

             do L = 1, num_spinstell
              curr_spinstell(numcomp_spinstell,L) = -0.25d0
             end do
9901       continue

! ? remove from the picture layers 5 and 6, by hyperpolarizing the respective axons
           go to 9902
             do L = 1, num_tuftIB   
              curr_tuftIB   (numcomp_tuftIB   ,L) = -0.25d0
             end do

             do L = 1, num_tuftRS   
              curr_tuftRS   (numcomp_tuftRS   ,L) = -0.25d0
             end do

             do L = 1, num_nontuftRS
              curr_nontuftRS(numcomp_nontuftRS,L) = -0.25d0
             end do

             do L = 1, num_deepbask 
              curr_deepbask (numcomp_deepbask ,L) = -0.25d0
             end do

             do L = 1, num_deepng   
              curr_deepng   (numcomp_deepng   ,L) = -0.25d0
             end do

             do L = 1, num_deepaxax 
              curr_deepaxax (numcomp_deepaxax ,L) = -0.25d0
             end do

             do L = 1, num_deepLTS  
              curr_deepLTS  (numcomp_deepLTS  ,L) = -0.25d0
             end do
9902       continue

       seed = 137.d0

       O = 0
       time = 0.d0

c CODE BELOW FOR "PICROTOXIN": scale all GABA-A
!        GOTO 30
c        z1 = 1.25d0  ! for intracortical IPSCs ! groucho84 uses 1.25
!        z1 = 1.00d0  ! for intracortical IPSCs
c        z1ap = 1.50d0  ! for intracortical IPSCs, basket, ng, and axoaxonal->princ.
         z1ap = 0.50d0  ! for intracortical IPSCs, basket, ng, and axoaxonal->princ.
c        z1ap = 3.00d0  ! for intracortical IPSCs, basket, ng, and axoaxonal->princ.
c        z1ai = 1.00d0  ! for intracortical IPSCs, basket and ng->inh.
         z1ai = 0.10d0  ! for intracortical IPSCs, basket and ng->inh.
!        z1b = 1.00d0  ! for intracortical IPSCs, LTS 
         z1bp =  0.05d0  ! for intracortical IPSCs, LTS -> princ. ! groucho84 in effect uses 1.25 
         z1bi = 1.00d0  ! for intracortical IPSCs, LTS -> inh.
         z2 = 1.00d0  ! for intrathalamic IPSCs, usual 1.00
      gGABA_supbask_to_suppyrRS   =  z1ap * gGABA_supbask_to_suppyrRS
      gGABA_supbask_to_suppyrFRB  =  z1ap * gGABA_supbask_to_suppyrFRB
      gGABA_supbask_to_supbask    =  z1ai * gGABA_supbask_to_supbask
      gGABA_supbask_to_supng      =  z1ai * gGABA_supbask_to_supng  
      gGABA_supbask_to_supaxax    =  z1ai * gGABA_supbask_to_supaxax
      gGABA_supbask_to_supLTS     =  z1ai * gGABA_supbask_to_supLTS
      gGABA_supbask_to_spinstell  =  z1ap * gGABA_supbask_to_spinstell

      gGABA_supng_to_suppyrRS   =  z1ap * gGABA_supng_to_suppyrRS
      gGABA_supng_to_suppyrFRB  =  z1ap * gGABA_supng_to_suppyrFRB
      gGABA_supng_to_nontuftRS  =  z1ap * gGABA_supng_to_nontuftRS
      gGABA_supng_to_tuftIB     =  z1ap * gGABA_supng_to_tuftIB   
      gGABA_supng_to_tuftRS     =  z1ap * gGABA_supng_to_tuftRS   
      gGABA_supng_to_supng      =  z1ai * gGABA_supng_to_supng    
      gGABA_supng_to_supbask    =  z1ai * gGABA_supng_to_supbask  

      gGABA_supaxax_to_suppyrRS   =  z1ap * gGABA_supaxax_to_suppyrRS
      gGABA_supaxax_to_suppyrFRB  =  z1ap * gGABA_supaxax_to_suppyrFRB
      gGABA_supaxax_to_spinstell  =  z1ap * gGABA_supaxax_to_spinstell
      gGABA_supaxax_to_tuftIB     =  z1ap * gGABA_supaxax_to_tuftIB
      gGABA_supaxax_to_tuftRS     =  z1ap * gGABA_supaxax_to_tuftRS
      gGABA_supaxax_to_nontuftRS  =  z1ap * gGABA_supaxax_to_nontuftRS

      gGABA_supLTS_to_suppyrRS    =  z1bp * gGABA_supLTS_to_suppyrRS
      gGABA_supLTS_to_suppyrFRB   =  z1bp * gGABA_supLTS_to_suppyrFRB
      gGABA_supLTS_to_supbask     =  z1bi * gGABA_supLTS_to_supbask
      gGABA_supLTS_to_supaxax     =  z1bi * gGABA_supLTS_to_supaxax
      gGABA_supLTS_to_supLTS      =  z1bi * gGABA_supLTS_to_supLTS
      gGABA_supLTS_to_spinstell   =  z1bp * gGABA_supLTS_to_spinstell
      gGABA_supLTS_to_tuftIB      =  z1bp * gGABA_supLTS_to_tuftIB
      gGABA_supLTS_to_tuftRS      =  z1bp * gGABA_supLTS_to_tuftRS
      gGABA_supLTS_to_deepbask    =  z1bi * gGABA_supLTS_to_deepbask
      gGABA_supLTS_to_deepaxax    =  z1bi * gGABA_supLTS_to_deepaxax
      gGABA_supLTS_to_deepLTS     =  z1bi * gGABA_supLTS_to_deepLTS
      gGABA_supLTS_to_nontuftRS   =  z1bp * gGABA_supLTS_to_nontuftRS

      gGABA_deepbask_to_spinstell =  z1ap * gGABA_deepbask_to_spinstell
      gGABA_deepbask_to_tuftIB    =  z1ap * gGABA_deepbask_to_tuftIB
      gGABA_deepbask_to_tuftRS    =  z1ap * gGABA_deepbask_to_tuftRS
      gGABA_deepbask_to_deepbask  =  z1ai * gGABA_deepbask_to_deepbask
      gGABA_deepbask_to_deepng    =  z1ai * gGABA_deepbask_to_deepng  
      gGABA_deepbask_to_deepaxax  =  z1ai * gGABA_deepbask_to_deepaxax
      gGABA_deepbask_to_deepLTS   =  z1ai * gGABA_deepbask_to_deepLTS
      gGABA_deepbask_to_nontuftRS =  z1ap * gGABA_deepbask_to_nontuftRS

      gGABA_deepng_to_tuftIB    =  z1ap * gGABA_deepng_to_tuftIB
      gGABA_deepng_to_tuftRS    =  z1ap * gGABA_deepng_to_tuftRS
      gGABA_deepng_to_nontuftRS =  z1ap * gGABA_deepng_to_nontuftRS
      gGABA_deepng_to_spinstell =  z1ap * gGABA_deepng_to_spinstell
      gGABA_deepng_to_deepng    =  z1ai * gGABA_deepng_to_deepng   
      gGABA_deepng_to_deepbask  =  z1ai * gGABA_deepng_to_deepbask 

      gGABA_deepaxax_to_suppyrRS   = z1ap * gGABA_deepaxax_to_suppyrRS
      gGABA_deepaxax_to_suppyrFRB  = z1ap * gGABA_deepaxax_to_suppyrFRB
      gGABA_deepaxax_to_spinstell  = z1ap * gGABA_deepaxax_to_spinstell
      gGABA_deepaxax_to_tuftIB     = z1ap * gGABA_deepaxax_to_tuftIB
      gGABA_deepaxax_to_tuftRS     = z1ap * gGABA_deepaxax_to_tuftRS
      gGABA_deepaxax_to_nontuftRS  = z1ap * gGABA_deepaxax_to_nontuftRS

      gGABA_deepLTS_to_suppyrRS    = z1bp * gGABA_deepLTS_to_suppyrRS
      gGABA_deepLTS_to_suppyrFRB   = z1bp * gGABA_deepLTS_to_suppyrFRB
      gGABA_deepLTS_to_supbask     = z1bi * gGABA_deepLTS_to_supbask
      gGABA_deepLTS_to_supaxax     = z1bi * gGABA_deepLTS_to_supaxax
      gGABA_deepLTS_to_supLTS      = z1bi * gGABA_deepLTS_to_supLTS
      gGABA_deepLTS_to_spinstell   = z1bp * gGABA_deepLTS_to_spinstell
      gGABA_deepLTS_to_tuftIB      = z1bp * gGABA_deepLTS_to_tuftIB
      gGABA_deepLTS_to_tuftRS      = z1bp * gGABA_deepLTS_to_tuftRS
      gGABA_deepLTS_to_deepbask    = z1bi * gGABA_deepLTS_to_deepbask
      gGABA_deepLTS_to_deepaxax    = z1bi * gGABA_deepLTS_to_deepaxax
      gGABA_deepLTS_to_deepLTS     = z1bi * gGABA_deepLTS_to_deepLTS
      gGABA_deepLTS_to_nontuftRS   = z1bp * gGABA_deepLTS_to_nontuftRS

        do L = 1, num_nRT
      gGABA_nRT_to_TCR(L)          = z2 * gGABA_nRT_to_TCR(L) 
        end do
      gGABA_nRT_to_nRT             = z2 * gGABA_nRT_to_nRT
30          CONTINUE
c End "PICROTOXIN" code

c "CGP" section: scale GABA-B conductances.
c            z7 = 1.5d0
             z7 = 3.0d0
!            z7 = 0.d0
       gGABAB_supng_to_suppyrRS  = z7*gGABAB_supng_to_suppyrRS
       gGABAB_supng_to_suppyrFRB = z7*gGABAB_supng_to_suppyrFRB
       gGABAB_supng_to_nontuftRS = z7*gGABAB_supng_to_nontuftRS
       gGABAB_supng_to_tuftIB    = z7*gGABAB_supng_to_tuftIB   
       gGABAB_supng_to_tuftRS    = z7*gGABAB_supng_to_tuftRS   

       gGABAB_deepng_to_tuftIB   = z7*gGABAB_deepng_to_tuftIB
       gGABAB_deepng_to_tuftRS   = z7*gGABAB_deepng_to_tuftRS
       gGABAB_deepng_to_nontuftRS= z7*gGABAB_deepng_to_nontuftRS
       gGABAB_deepng_to_spinstell= z7*gGABAB_deepng_to_spinstell
31           CONTINUE
c End CGP section

! Code below is "NBQX": scale all AMPA; see also below for possibility
! of further additional scaling of connections between layers
!        GOTO 35
!          z1 = 1.00d0  ! intracortical e/i
c          z1 = 2.00d0  ! intracortical e/i ! usual 1.00; use 2.0 for delta78
           z1 = 0.10d0  ! intracortical e/i ! usual 1.00; use 2.0 for delta78
           z3 = 0.00d0  ! TCR -> cortical i ! usual 1.0
           z4 = 1.00d0  ! TCR -> nRT & nontuftRS ->nRT ! usual 1.00
c          z5 = 0.25d0  ! spinstell -> spinstell; may reduce as in spindle series, 8 May'04
           z5 = 0.10d0  ! spinstell -> spinstell; may reduce as in spindle series, 8 May'04
!          z5 = 0.00d0  ! spinstell -> spinstell; may reduce as in spindle series, 8 May'04
c          z6 = 0.10d0    ! layer 5 tuftIB or RS -> layer 5 tuftIB or RS
           z6 = 0.05d0    ! layer 5 tuftIB or RS -> layer 5 tuftIB or RS; 16 May '07, further reduction
c          z6 = 1.00d0    ! layer 5 tuftIB or RS -> layer 5 tuftIB or RS
!          z2 = 2.00d0  ! everything else; note that this may be INCREASED, usual 1.0
c In groucho84, z2 = 2.00d0
           z2 = 0.20d0  ! everything else; note that this may be INCREASED, usual 1.0

      gAMPA_suppyrRS_to_suppyrRS= z2 * gAMPA_suppyrRS_to_suppyrRS
      gAMPA_suppyrRS_to_suppyrFRB= z2 * gAMPA_suppyrRS_to_suppyrFRB
      gAMPA_suppyrRS_to_supbask  = z1 * gAMPA_suppyrRS_to_supbask
      gAMPA_suppyrRS_to_supng    = z1 * gAMPA_suppyrRS_to_supng  
      gAMPA_suppyrRS_to_supaxax  = z1 * gAMPA_suppyrRS_to_supaxax
      gAMPA_suppyrRS_to_supLTS   = z1 * gAMPA_suppyrRS_to_supLTS
      gAMPA_suppyrRS_to_spinstell= z2 * gAMPA_suppyrRS_to_spinstell
      gAMPA_suppyrRS_to_tuftIB   = z2 * gAMPA_suppyrRS_to_tuftIB
      gAMPA_suppyrRS_to_tuftRS   = z2 * gAMPA_suppyrRS_to_tuftRS
      gAMPA_suppyrRS_to_deepbask = z1 * gAMPA_suppyrRS_to_deepbask
      gAMPA_suppyrRS_to_deepaxax = z1 * gAMPA_suppyrRS_to_deepaxax
      gAMPA_suppyrRS_to_deepLTS  = z1 * gAMPA_suppyrRS_to_deepLTS
      gAMPA_suppyrRS_to_nontuftRS= z2 * gAMPA_suppyrRS_to_nontuftRS

      gAMPA_suppyrFRB_to_suppyrRS= z2 * gAMPA_suppyrFRB_to_suppyrRS
      gAMPA_suppyrFRB_to_suppyrFRB=z2 * gAMPA_suppyrFRB_to_suppyrFRB
      gAMPA_suppyrFRB_to_supbask  =z1 * gAMPA_suppyrFRB_to_supbask
      gAMPA_suppyrFRB_to_supng    =z1 * gAMPA_suppyrFRB_to_supng  
      gAMPA_suppyrFRB_to_supaxax  =z1 * gAMPA_suppyrFRB_to_supaxax
      gAMPA_suppyrFRB_to_supLTS   =z1 * gAMPA_suppyrFRB_to_supLTS
      gAMPA_suppyrFRB_to_spinstell=z2 * gAMPA_suppyrFRB_to_spinstell
      gAMPA_suppyrFRB_to_tuftIB   =z2 * gAMPA_suppyrFRB_to_tuftIB
      gAMPA_suppyrFRB_to_tuftRS   =z2 * gAMPA_suppyrFRB_to_tuftRS
      gAMPA_suppyrFRB_to_deepbask =z1 * gAMPA_suppyrFRB_to_deepbask
      gAMPA_suppyrFRB_to_deepaxax =z1 * gAMPA_suppyrFRB_to_deepaxax
      gAMPA_suppyrFRB_to_deepLTS  =z1 * gAMPA_suppyrFRB_to_deepLTS
      gAMPA_suppyrFRB_to_nontuftRS=z2 * gAMPA_suppyrFRB_to_nontuftRS

      gAMPA_spinstell_to_suppyrRS = z2 * gAMPA_spinstell_to_suppyrRS
      gAMPA_spinstell_to_suppyrFRB= z2 * gAMPA_spinstell_to_suppyrFRB
      gAMPA_spinstell_to_supbask  = z1 * gAMPA_spinstell_to_supbask
      gAMPA_spinstell_to_supaxax  = z1 * gAMPA_spinstell_to_supaxax
      gAMPA_spinstell_to_supLTS   = z1 * gAMPA_spinstell_to_supLTS
      gAMPA_spinstell_to_spinstell= z5 * gAMPA_spinstell_to_spinstell
      gAMPA_spinstell_to_tuftIB   = z2 * gAMPA_spinstell_to_tuftIB
      gAMPA_spinstell_to_tuftRS   = z2 * gAMPA_spinstell_to_tuftRS
      gAMPA_spinstell_to_deepbask = z1 * gAMPA_spinstell_to_deepbask
      gAMPA_spinstell_to_deepng   = z1 * gAMPA_spinstell_to_deepng  
      gAMPA_spinstell_to_deepaxax = z1 * gAMPA_spinstell_to_deepaxax
      gAMPA_spinstell_to_deepLTS  = z1 * gAMPA_spinstell_to_deepLTS
      gAMPA_spinstell_to_nontuftRS= z2 * gAMPA_spinstell_to_nontuftRS

      gAMPA_tuftIB_to_suppyrRS    = z2 * gAMPA_tuftIB_to_suppyrRS
      gAMPA_tuftIB_to_suppyrFRB   = z2 * gAMPA_tuftIB_to_suppyrFRB
      gAMPA_tuftIB_to_supbask     = z1 * gAMPA_tuftIB_to_supbask
      gAMPA_tuftIB_to_supaxax     = z1 * gAMPA_tuftIB_to_supaxax
      gAMPA_tuftIB_to_supLTS      = z1 * gAMPA_tuftIB_to_supLTS
      gAMPA_tuftIB_to_spinstell   = z2 * gAMPA_tuftIB_to_spinstell
      gAMPA_tuftIB_to_tuftIB      = z6 * gAMPA_tuftIB_to_tuftIB
      gAMPA_tuftIB_to_tuftRS      = z6 * gAMPA_tuftIB_to_tuftRS
      gAMPA_tuftIB_to_deepbask    = z1 * gAMPA_tuftIB_to_deepbask
      gAMPA_tuftIB_to_deepng      = z1 * gAMPA_tuftIB_to_deepng  
      gAMPA_tuftIB_to_deepaxax    = z1 * gAMPA_tuftIB_to_deepaxax
      gAMPA_tuftIB_to_deepLTS     = z1 * gAMPA_tuftIB_to_deepLTS
      gAMPA_tuftIB_to_nontuftRS   = z2 * gAMPA_tuftIB_to_nontuftRS

      gAMPA_tuftRS_to_suppyrRS    = z2 * gAMPA_tuftRS_to_suppyrRS
      gAMPA_tuftRS_to_suppyrFRB   = z2 * gAMPA_tuftRS_to_suppyrFRB
      gAMPA_tuftRS_to_supbask     = z1 * gAMPA_tuftRS_to_supbask 
      gAMPA_tuftRS_to_supaxax     = z1 * gAMPA_tuftRS_to_supaxax
      gAMPA_tuftRS_to_supLTS      = z1 * gAMPA_tuftRS_to_supLTS
      gAMPA_tuftRS_to_spinstell   = z2 * gAMPA_tuftRS_to_spinstell
      gAMPA_tuftRS_to_tuftIB      = z6 * gAMPA_tuftRS_to_tuftIB
      gAMPA_tuftRS_to_tuftRS      = z6 * gAMPA_tuftRS_to_tuftRS
      gAMPA_tuftRS_to_deepbask    = z1 * gAMPA_tuftRS_to_deepbask
      gAMPA_tuftRS_to_deepng      = z1 * gAMPA_tuftRS_to_deepng  
      gAMPA_tuftRS_to_deepaxax    = z1 * gAMPA_tuftRS_to_deepaxax
      gAMPA_tuftRS_to_deepLTS     = z1 * gAMPA_tuftRS_to_deepLTS
      gAMPA_tuftRS_to_nontuftRS   = z2 * gAMPA_tuftRS_to_nontuftRS

      gAMPA_TCR_to_suppyrRS        = z2 * gAMPA_TCR_to_suppyrRS
      gAMPA_TCR_to_suppyrFRB       = z2 * gAMPA_TCR_to_suppyrFRB
      gAMPA_TCR_to_supbask         = z3 * gAMPA_TCR_to_supbask
      gAMPA_TCR_to_supng           = z3 * gAMPA_TCR_to_supng   
      gAMPA_TCR_to_supaxax         = z3 * gAMPA_TCR_to_supaxax
      gAMPA_TCR_to_spinstell       = z2 * gAMPA_TCR_to_spinstell
      gAMPA_TCR_to_tuftIB          = z2 * gAMPA_TCR_to_tuftIB
      gAMPA_TCR_to_tuftRS          = z2 * gAMPA_TCR_to_tuftRS
      gAMPA_TCR_to_deepbask        = z3 * gAMPA_TCR_to_deepbask
      gAMPA_TCR_to_deepng          = z3 * gAMPA_TCR_to_deepng  
      gAMPA_TCR_to_deepaxax        = z3 * gAMPA_TCR_to_deepaxax
      gAMPA_TCR_to_nRT             = z4 * gAMPA_TCR_to_nRT
      gAMPA_TCR_to_nontuftRS       = z2 * gAMPA_TCR_to_nontuftRS

      gAMPA_nontuftRS_to_suppyrRS  = z2 * gAMPA_nontuftRS_to_suppyrRS
      gAMPA_nontuftRS_to_suppyrFRB = z2 * gAMPA_nontuftRS_to_suppyrFRB
      gAMPA_nontuftRS_to_supbask   = z1 * gAMPA_nontuftRS_to_supbask
      gAMPA_nontuftRS_to_supaxax   = z1 * gAMPA_nontuftRS_to_supaxax
      gAMPA_nontuftRS_to_supLTS    = z1 * gAMPA_nontuftRS_to_supLTS
      gAMPA_nontuftRS_to_spinstell = z2 * gAMPA_nontuftRS_to_spinstell
      gAMPA_nontuftRS_to_tuftIB    = z2 * gAMPA_nontuftRS_to_tuftIB
      gAMPA_nontuftRS_to_tuftRS    = z2 * gAMPA_nontuftRS_to_tuftRS
      gAMPA_nontuftRS_to_deepbask  = z1 * gAMPA_nontuftRS_to_deepbask
      gAMPA_nontuftRS_to_deepng    = z1 * gAMPA_nontuftRS_to_deepng  
      gAMPA_nontuftRS_to_deepaxax  = z1 * gAMPA_nontuftRS_to_deepaxax
      gAMPA_nontuftRS_to_deepLTS   = z1 * gAMPA_nontuftRS_to_deepLTS
      gAMPA_nontuftRS_to_TCR       = z2 * gAMPA_nontuftRS_to_TCR
      gAMPA_nontuftRS_to_nRT       = z4 * gAMPA_nontuftRS_to_nRT
      gAMPA_nontuftRS_to_nontuftRS = z2 * gAMPA_nontuftRS_to_nontuftRS

! Code below: allows for
! further additional scaling of connections between layers
      z10a = 1.d0 ! scales deep pyramids to superficial excitatory cells
      z10b = 0.5d0 ! scales deep pyramids to superficial inhibitory cells
      z12 = 1.d0 ! scales superficial pyramids to deep cells & spinstell

      gAMPA_suppyrRS_to_spinstell= z12* gAMPA_suppyrRS_to_spinstell
      gAMPA_suppyrRS_to_tuftIB   = z12* gAMPA_suppyrRS_to_tuftIB
      gAMPA_suppyrRS_to_tuftRS   = z12* gAMPA_suppyrRS_to_tuftRS
      gAMPA_suppyrRS_to_deepbask = z12* gAMPA_suppyrRS_to_deepbask
      gAMPA_suppyrRS_to_deepaxax = z12* gAMPA_suppyrRS_to_deepaxax
      gAMPA_suppyrRS_to_deepLTS  = z12* gAMPA_suppyrRS_to_deepLTS
      gAMPA_suppyrRS_to_nontuftRS= z12* gAMPA_suppyrRS_to_nontuftRS

      gAMPA_suppyrFRB_to_spinstell=z12* gAMPA_suppyrFRB_to_spinstell
      gAMPA_suppyrFRB_to_tuftIB   =z12* gAMPA_suppyrFRB_to_tuftIB
      gAMPA_suppyrFRB_to_tuftRS   =z12* gAMPA_suppyrFRB_to_tuftRS
      gAMPA_suppyrFRB_to_deepbask =z12* gAMPA_suppyrFRB_to_deepbask
      gAMPA_suppyrFRB_to_deepaxax =z12* gAMPA_suppyrFRB_to_deepaxax
      gAMPA_suppyrFRB_to_deepLTS  =z12* gAMPA_suppyrFRB_to_deepLTS
      gAMPA_suppyrFRB_to_nontuftRS=z12* gAMPA_suppyrFRB_to_nontuftRS


      gAMPA_tuftIB_to_suppyrRS    = z10a* gAMPA_tuftIB_to_suppyrRS
      gAMPA_tuftIB_to_suppyrFRB   = z10a* gAMPA_tuftIB_to_suppyrFRB
      gAMPA_tuftIB_to_supbask     = z10b* gAMPA_tuftIB_to_supbask
      gAMPA_tuftIB_to_supaxax     = z10b* gAMPA_tuftIB_to_supaxax
      gAMPA_tuftIB_to_supLTS      = z10b* gAMPA_tuftIB_to_supLTS

      gAMPA_tuftRS_to_suppyrRS    = z10a* gAMPA_tuftRS_to_suppyrRS
      gAMPA_tuftRS_to_suppyrFRB   = z10a* gAMPA_tuftRS_to_suppyrFRB
      gAMPA_tuftRS_to_supbask     = z10b* gAMPA_tuftRS_to_supbask 
      gAMPA_tuftRS_to_supaxax     = z10b* gAMPA_tuftRS_to_supaxax
      gAMPA_tuftRS_to_supLTS      = z10b* gAMPA_tuftRS_to_supLTS

      gAMPA_nontuftRS_to_suppyrRS  = z10a* gAMPA_nontuftRS_to_suppyrRS
      gAMPA_nontuftRS_to_suppyrFRB = z10a* gAMPA_nontuftRS_to_suppyrFRB
      gAMPA_nontuftRS_to_supbask   = z10b* gAMPA_nontuftRS_to_supbask
      gAMPA_nontuftRS_to_supaxax   = z10b* gAMPA_nontuftRS_to_supaxax
      gAMPA_nontuftRS_to_supLTS    = z10b* gAMPA_nontuftRS_to_supLTS
35         CONTINUE
c End "NBQX" section.

c Code below scales TCR output to cortex (not to nRT), AMPA & NMDA
!     goto 60
c      z = 1.d0
       z = 0.d0

      gAMPA_TCR_to_suppyrRS = z * gAMPA_TCR_to_suppyrRS
      gNMDA_TCR_to_suppyrRS = z * gNMDA_TCR_to_suppyrRS
      gAMPA_TCR_to_suppyrFRB = z * gAMPA_TCR_to_suppyrFRB
      gNMDA_TCR_to_suppyrFRB = z * gNMDA_TCR_to_suppyrFRB
      gAMPA_TCR_to_supbask = z * gAMPA_TCR_to_supbask
      gNMDA_TCR_to_supbask = z * gNMDA_TCR_to_supbask
      gAMPA_TCR_to_supaxax = z * gAMPA_TCR_to_supaxax
      gNMDA_TCR_to_supaxax = z * gNMDA_TCR_to_supaxax
      gAMPA_TCR_to_spinstell = z * gAMPA_TCR_to_spinstell
      gNMDA_TCR_to_spinstell = z * gNMDA_TCR_to_spinstell
      gAMPA_TCR_to_tuftIB = z * gAMPA_TCR_to_tuftIB
      gNMDA_TCR_to_tuftIB = z * gNMDA_TCR_to_tuftIB
      gAMPA_TCR_to_tuftRS = z * gAMPA_TCR_to_tuftRS
      gNMDA_TCR_to_tuftRS = z * gNMDA_TCR_to_tuftRS
      gAMPA_TCR_to_deepbask = z * gAMPA_TCR_to_deepbask
      gNMDA_TCR_to_deepbask = z * gNMDA_TCR_to_deepbask
      gAMPA_TCR_to_deepaxax = z * gAMPA_TCR_to_deepaxax
      gNMDA_TCR_to_deepaxax = z * gNMDA_TCR_to_deepaxax
      gAMPA_TCR_to_nontuftRS = z * gAMPA_TCR_to_nontuftRS
      gNMDA_TCR_to_nontuftRS = z * gNMDA_TCR_to_nontuftRS

60          CONTINUE

c Code below scales some/all NMDA conductances. APV.
!        GOTO 40
c        z1 = 0.0d0 ! to interneurons
         z1 = 0.5d0 ! to interneurons
c        z1 = 0.0d0 ! to interneurons; = 1 in delta85
! Usual scaling of NMDA to princ. cells, including FRB, is 0.5
         z2 = 0.25d0 ! to  cort. principal cells, except FRB
c        z2 = 2.0d0 ! to  cort. principal cells, except FRB; = 1 for delta79
c        z2 = 0.0d0 ! to  cort. principal cells, except FRB; = 1 for delta79,= 2 for delta85
         z3 = 0.0d0 ! to suppyrFRB
         z4 = 0.0d0  ! to TCR and nRT and from TCR to cort. princ.
c        z5 = 1.25d0  ! spinstell to spinstell
         z5 = 0.00d0  ! spinstell to spinstell
!        z5 = 0.00d0  ! spinstell to spinstell
      gNMDA_suppyrRS_to_suppyrRS= z2 *
     &  gNMDA_suppyrRS_to_suppyrRS
      gNMDA_suppyrRS_to_suppyrFRB= z3 *
     &  gNMDA_suppyrRS_to_suppyrFRB
      gNMDA_suppyrRS_to_supbask  = z1 *
     &  gNMDA_suppyrRS_to_supbask
      gNMDA_suppyrRS_to_supng    = z1 *
     &  gNMDA_suppyrRS_to_supng  
      gNMDA_suppyrRS_to_supaxax  = z1 *
     &  gNMDA_suppyrRS_to_supaxax
      gNMDA_suppyrRS_to_supLTS   = z1 *
     &  gNMDA_suppyrRS_to_supLTS   
      gNMDA_suppyrRS_to_spinstell= z2 *
     &  gNMDA_suppyrRS_to_spinstell
      gNMDA_suppyrRS_to_tuftIB   = z2 *
     &  gNMDA_suppyrRS_to_tuftIB
      gNMDA_suppyrRS_to_tuftRS   = z2 *
     &  gNMDA_suppyrRS_to_tuftRS  
      gNMDA_suppyrRS_to_deepbask = z1 *
     &  gNMDA_suppyrRS_to_deepbask 
      gNMDA_suppyrRS_to_deepaxax = z1 *
     &  gNMDA_suppyrRS_to_deepaxax
      gNMDA_suppyrRS_to_deepLTS  = z1 *
     &  gNMDA_suppyrRS_to_deepLTS 
      gNMDA_suppyrRS_to_nontuftRS= z2 *
     &  gNMDA_suppyrRS_to_nontuftRS
 
      gNMDA_suppyrFRB_to_suppyrRS= z2 *
     &  gNMDA_suppyrFRB_to_suppyrRS
      gNMDA_suppyrFRB_to_suppyrFRB= z3 *
     &  gNMDA_suppyrFRB_to_suppyrFRB
      gNMDA_suppyrFRB_to_supbask  = z1 *
     &  gNMDA_suppyrFRB_to_suppyrFRB
      gNMDA_suppyrFRB_to_supng    = z1 *
     &  gNMDA_suppyrFRB_to_supng   
      gNMDA_suppyrFRB_to_supaxax  = z1 *
     &  gNMDA_suppyrFRB_to_supaxax 
      gNMDA_suppyrFRB_to_supLTS   = z1 *
     &  gNMDA_suppyrFRB_to_supLTS
      gNMDA_suppyrFRB_to_spinstell= z2 *
     &  gNMDA_suppyrFRB_to_spinstell
      gNMDA_suppyrFRB_to_tuftIB   = z2 *
     &  gNMDA_suppyrFRB_to_tuftIB
      gNMDA_suppyrFRB_to_tuftRS   = z2 *
     &  gNMDA_suppyrFRB_to_tuftRS   
      gNMDA_suppyrFRB_to_deepbask = z1 *
     &  gNMDA_suppyrFRB_to_deepbask
      gNMDA_suppyrFRB_to_deepaxax = z1 *
     &  gNMDA_suppyrFRB_to_deepaxax
      gNMDA_suppyrFRB_to_deepLTS  = z1 *
     &  gNMDA_suppyrFRB_to_deepLTS
      gNMDA_suppyrFRB_to_nontuftRS= z2 *
     &  gNMDA_suppyrFRB_to_nontuftRS

      gNMDA_spinstell_to_suppyrRS = z2 *
     &  gNMDA_spinstell_to_suppyrRS
      gNMDA_spinstell_to_suppyrFRB= z3 *
     &  gNMDA_spinstell_to_suppyrFRB
      gNMDA_spinstell_to_supbask  = z1 *
     &  gNMDA_spinstell_to_supbask
      gNMDA_spinstell_to_supaxax  = z1 *
     &  gNMDA_spinstell_to_supaxax 
      gNMDA_spinstell_to_supLTS   = z1 *
     &  gNMDA_spinstell_to_supLTS
      gNMDA_spinstell_to_spinstell= z5 *
     &  gNMDA_spinstell_to_spinstell
      gNMDA_spinstell_to_tuftIB   = z2 *
     &  gNMDA_spinstell_to_tuftIB 
      gNMDA_spinstell_to_tuftRS   = z2 *
     &  gNMDA_spinstell_to_tuftRS 
      gNMDA_spinstell_to_deepbask = z1 *
     &  gNMDA_spinstell_to_deepbask 
      gNMDA_spinstell_to_deepng   = z1 *
     &  gNMDA_spinstell_to_deepng   
      gNMDA_spinstell_to_deepaxax = z1 *
     &  gNMDA_spinstell_to_deepaxax
      gNMDA_spinstell_to_deepLTS  = z1 *
     &  gNMDA_spinstell_to_deepLTS 
      gNMDA_spinstell_to_nontuftRS= z2 *
     &  gNMDA_spinstell_to_nontuftRS

      gNMDA_tuftIB_to_suppyrRS    = z2 *
     &  gNMDA_tuftIB_to_suppyrRS 
      gNMDA_tuftIB_to_suppyrFRB   = z3 *
     &  gNMDA_tuftIB_to_suppyrFRB
      gNMDA_tuftIB_to_supbask     = z1 *
     &  gNMDA_tuftIB_to_supbask 
      gNMDA_tuftIB_to_supaxax     = z1 *
     &  gNMDA_tuftIB_to_supaxax 
      gNMDA_tuftIB_to_supLTS      = z1 *
     &  gNMDA_tuftIB_to_supLTS 
      gNMDA_tuftIB_to_spinstell   = z2 *
     &  gNMDA_tuftIB_to_spinstell 
      gNMDA_tuftIB_to_tuftIB      = z2 *
     &  gNMDA_tuftIB_to_tuftIB 
      gNMDA_tuftIB_to_tuftRS      = z2 *
     &  gNMDA_tuftIB_to_tuftRS  
      gNMDA_tuftIB_to_deepbask    = z1 *
     &  gNMDA_tuftIB_to_deepbask 
      gNMDA_tuftIB_to_deepng      = z1 *
     &  gNMDA_tuftIB_to_deepng   
      gNMDA_tuftIB_to_deepaxax    = z1 *
     &  gNMDA_tuftIB_to_deepaxax
      gNMDA_tuftIB_to_deepLTS     = z1 *
     &  gNMDA_tuftIB_to_deepLTS   
      gNMDA_tuftIB_to_nontuftRS   = z2 *
     &  gNMDA_tuftIB_to_nontuftRS  

      gNMDA_tuftRS_to_suppyrRS    = z2 *
     &  gNMDA_tuftRS_to_suppyrRS
      gNMDA_tuftRS_to_suppyrFRB   = z3 *
     &  gNMDA_tuftRS_to_suppyrFRB
      gNMDA_tuftRS_to_supbask     = z1 *
     &  gNMDA_tuftRS_to_supbask 
      gNMDA_tuftRS_to_supaxax     = z1 *
     &  gNMDA_tuftRS_to_supaxax 
      gNMDA_tuftRS_to_supLTS      = z1 *
     &  gNMDA_tuftRS_to_supLTS   
      gNMDA_tuftRS_to_spinstell   = z2 *
     &  gNMDA_tuftRS_to_spinstell  
      gNMDA_tuftRS_to_tuftIB      = z2 *
     &  gNMDA_tuftRS_to_tuftIB
      gNMDA_tuftRS_to_tuftRS      = z2 *
     &  gNMDA_tuftRS_to_tuftRS 
      gNMDA_tuftRS_to_deepbask    = z1 *
     &  gNMDA_tuftRS_to_deepbask
      gNMDA_tuftRS_to_deepng      = z1 *
     &  gNMDA_tuftRS_to_deepng  
      gNMDA_tuftRS_to_deepaxax    = z1 *
     &  gNMDA_tuftRS_to_deepaxax
      gNMDA_tuftRS_to_deepLTS     = z1 *
     &  gNMDA_tuftRS_to_deepLTS   
      gNMDA_tuftRS_to_nontuftRS   = z2 *
     &  gNMDA_tuftRS_to_nontuftRS 

      gNMDA_TCR_to_suppyrRS        = z4 *
     &  gNMDA_TCR_to_suppyrRS 
      gNMDA_TCR_to_suppyrFRB       = z4 *
     &  gNMDA_TCR_to_suppyrFRB 
      gNMDA_TCR_to_supbask         = z1 *
     &  gNMDA_TCR_to_supbask
      gNMDA_TCR_to_supng           = z1 *
     &  gNMDA_TCR_to_supng  
      gNMDA_TCR_to_supaxax         = z1 *
     &  gNMDA_TCR_to_supaxax 
      gNMDA_TCR_to_spinstell       = z4 *
     &  gNMDA_TCR_to_spinstell 
      gNMDA_TCR_to_tuftIB          = z4 *
     &  gNMDA_TCR_to_tuftIB   
      gNMDA_TCR_to_tuftRS          = z4 *
     &  gNMDA_TCR_to_tuftRS 
      gNMDA_TCR_to_deepbask        = z1 *
     &  gNMDA_TCR_to_deepbask 
      gNMDA_TCR_to_deepng          = z1 *
     &  gNMDA_TCR_to_deepng   
      gNMDA_TCR_to_deepaxax        = z1 *
     &  gNMDA_TCR_to_deepaxax 
      gNMDA_TCR_to_nRT             = z1 *
     &  gNMDA_TCR_to_nRT  
      gNMDA_TCR_to_nontuftRS       = z4 *
     &  gNMDA_TCR_to_nontuftRS  

      gNMDA_nontuftRS_to_suppyrRS  = z2 *
     &  gNMDA_nontuftRS_to_suppyrRS
      gNMDA_nontuftRS_to_suppyrFRB = z3 *
     & gNMDA_nontuftRS_to_suppyrFRB 
      gNMDA_nontuftRS_to_supbask   = z1 *
     &  gNMDA_nontuftRS_to_supbask 
      gNMDA_nontuftRS_to_supaxax   = z1 *
     &  gNMDA_nontuftRS_to_supaxax  
      gNMDA_nontuftRS_to_supLTS    = z1 *
     &  gNMDA_nontuftRS_to_supLTS 
      gNMDA_nontuftRS_to_spinstell = z2 *
     &  gNMDA_nontuftRS_to_spinstell 
      gNMDA_nontuftRS_to_tuftIB    = z2 *
     &  gNMDA_nontuftRS_to_tuftIB 
      gNMDA_nontuftRS_to_tuftRS    = z2 *
     &  gNMDA_nontuftRS_to_tuftRS 
      gNMDA_nontuftRS_to_deepbask  = z1 *
     & gNMDA_nontuftRS_to_deepbask
      gNMDA_nontuftRS_to_deepaxax  = z1 *
     &  gNMDA_nontuftRS_to_deepaxax 
      gNMDA_nontuftRS_to_deepLTS   = z1 *
     &  gNMDA_nontuftRS_to_deepLTS
      gNMDA_nontuftRS_to_TCR       = z4 *
     &  gNMDA_nontuftRS_to_TCR 
      gNMDA_nontuftRS_to_nRT       = z4 *
     &  gNMDA_nontuftRS_to_nRT    
      gNMDA_nontuftRS_to_nontuftRS = z2 *
     &  gNMDA_nontuftRS_to_nontuftRS 
40    CONTINUE
c End section scaling all NMDA conductances.       

c INITIALIZE ALL THE INTEGRATION SUBROUTINES
        initialize = 0
        firstcell = 1
        lastcell =  1
      IF (nodecell(thisno).eq.'suppyrRS ') then
       CALL INTEGRATE_suppyrRSXPB (O, time, num_suppyrRS,
     &    V_suppyrRS, curr_suppyrRS,
     &    initialize, firstcell, lastcell,
     & gAMPA_suppyrRS, gNMDA_suppyrRS, gGABA_A_suppyrRS,
     & gGABA_B_suppyrRS, Mg, 
     & gapcon_suppyrRS  ,totaxgj_suppyrRS   ,gjtable_suppyrRS, dt,
     & totaxgj_suppyr, gjtable_suppyr, num_suppyrFRB,
!    & vax_suppyrFRB,
     & v_suppyrFRB,
     &  chi_suppyrRS,mnaf_suppyrRS,mnap_suppyrRS,
     &  hnaf_suppyrRS,mkdr_suppyrRS,mka_suppyrRS,
     &  hka_suppyrRS,mk2_suppyrRS,hk2_suppyrRS,
     &  mkm_suppyrRS,mkc_suppyrRS,mkahp_suppyrRS,
     &  mcat_suppyrRS,hcat_suppyrRS,mcal_suppyrRS,
     &  mar_suppyrRS,field_1mm   ,field_2mm,rel_axonshift_suppyrRS)

      ELSE if (nodecell(thisno).eq.'suppyrFRB') then
       CALL INTEGRATE_suppyrFRBxPB (O, time, num_suppyrFRB,
     &    V_suppyrFRB, curr_suppyrFRB,
     &    initialize, firstcell, lastcell, 
     & gAMPA_suppyrFRB, gNMDA_suppyrFRB, gGABA_A_suppyrFRB,
     & gGABA_B_suppyrFRB, Mg, 
     & gapcon_suppyrFRB ,totaxgj_suppyrFRB  ,gjtable_suppyrFRB, dt,
     & totaxgj_suppyr, gjtable_suppyr, num_suppyrRS,
!    & vax_suppyrRS,
     & v_suppyrRS,
     &  chi_suppyrFRB,mnaf_suppyrFRB,mnap_suppyrFRB,
     &  hnaf_suppyrFRB,mkdr_suppyrFRB,mka_suppyrFRB,
     &  hka_suppyrFRB,mk2_suppyrFRB,hk2_suppyrFRB,
     &  mkm_suppyrFRB,mkc_suppyrFRB,mkahp_suppyrFRB,
     &  mcat_suppyrFRB,hcat_suppyrFRB,mcal_suppyrFRB,
     &  mar_suppyrFRB,field_1mm  ,field_2mm,rel_axonshift_suppyrFRB,
     & scale_suppyrFRB_gNaP)

      ELSE if (nodecell(thisno).eq.'supbask  ') then
       CALL INTEGRATE_supbaskx (O, time, num_supbask ,
     &    V_supbask , curr_supbask ,
     $    initialize, firstcell, lastcell,
     & gAMPA_supbask , gNMDA_supbask , gGABA_A_supbask ,
     & Mg, 
     & gapcon_supbask   ,totSDgj_supbask    ,gjtable_supbask , dt,
     &  chi_supbask,mnaf_supbask,mnap_supbask,
     &  hnaf_supbask,mkdr_supbask,mka_supbask,
     &  hka_supbask,mk2_supbask,hk2_supbask,
     &  mkm_supbask,mkc_supbask,mkahp_supbask,
     &  mcat_supbask,hcat_supbask,mcal_supbask,
     &  mar_supbask)

      ELSE if (nodecell(thisno).eq.'supng    ') then
       CALL INTEGRATE_supng    (O, time, num_supng   ,
     &    V_supng   , curr_supng   ,
     $    initialize, firstcell, lastcell,
     & gAMPA_supng   , gNMDA_supng   , gGABA_A_supng   ,
     & Mg, 
     & gapcon_supng     ,totSDgj_supng      ,gjtable_supng   , dt,
     &  chi_supng  ,mnaf_supng  ,mnap_supng  ,
     &  hnaf_supng  ,mkdr_supng  ,mka_supng  ,
     &  hka_supng  ,mk2_supng  ,hk2_supng  ,
     &  mkm_supng  ,mkc_supng  ,mkahp_supng  ,
     &  mcat_supng  ,hcat_supng  ,mcal_supng  ,
     &  mar_supng  )

      ELSE if (nodecell(thisno).eq.'supaxax  ') then
       CALL INTEGRATE_supaxaxx (O, time, num_supaxax ,
     &    V_supaxax , curr_supaxax ,
     &    initialize, firstcell, lastcell,
     & gAMPA_supaxax , gNMDA_supaxax , gGABA_A_supaxax ,
     & Mg, 
     & gapcon_supaxax   ,totSDgj_supaxax    ,gjtable_supaxax , dt,
     &  chi_supaxax,mnaf_supaxax,mnap_supaxax,
     &  hnaf_supaxax,mkdr_supaxax,mka_supaxax,
     &  hka_supaxax,mk2_supaxax,hk2_supaxax,
     &  mkm_supaxax,mkc_supaxax,mkahp_supaxax,
     &  mcat_supaxax,hcat_supaxax,mcal_supaxax,
     &  mar_supaxax)

      ELSE if (nodecell(thisno).eq.'supLTS   ') then
       CALL INTEGRATE_supLTSx  (O, time, num_supLTS  ,
     &    V_supLTS  , curr_supLTS  ,
     &    initialize, firstcell, lastcell,
     & gAMPA_supLTS  , gNMDA_supLTS  , gGABA_A_supLTS  ,
     & Mg, 
     & gapcon_supLTS    ,totSDgj_supLTS     ,gjtable_supLTS  , dt,
     &  chi_supLTS,mnaf_supLTS,mnap_supLTS,
     &  hnaf_supLTS,mkdr_supLTS,mka_supLTS,
     &  hka_supLTS,mk2_supLTS,hk2_supLTS,
     &  mkm_supLTS,mkc_supLTS,mkahp_supLTS,
     &  mcat_supLTS,hcat_supLTS,mcal_supLTS,
     &  mar_supLTS)

      ELSE if (nodecell(thisno).eq.'spinstell') then
       CALL INTEGRATE_spinstelldiegoxB (O, time, num_spinstell,
     &    V_spinstell, curr_spinstell,
     &    initialize, firstcell, lastcell,
     & gAMPA_spinstell, gNMDA_spinstell, gGABA_A_spinstell,
     & gGABA_B_spinstell, Mg, 
     & gapcon_spinstell,totaxgj_spinstell,gjtable_spinstell, dt,
     &  chi_spinstell,mnaf_spinstell,mnap_spinstell,
     &  hnaf_spinstell,mkdr_spinstell,mka_spinstell,
     &  hka_spinstell,mk2_spinstell,hk2_spinstell,
     &  mkm_spinstell,mkc_spinstell,mkahp_spinstell,
     &  mcat_spinstell,hcat_spinstell,mcal_spinstell,
     &  mar_spinstell)

      ELSE if (nodecell(thisno).eq.'tuftIB   ') then
       CALL INTEGRATE_tuftIBVx3B (O, time, num_tuftIB,
     &    V_tuftIB, curr_tuftIB,
     &  initialize, firstcell, lastcell,
     & gAMPA_tuftIB, gNMDA_tuftIB, gGABA_A_tuftIB,
     & gGABA_B_tuftIB, Mg, 
     & gapcon_tuftIB,totaxgj_tuftIB,gjtable_tuftIB, dt,
     & totaxgj_tuft  , gjtable_tuft  , num_tuftRS   ,
c    & vax_tuftRS   ,
     & v_tuftRS   ,
     &  chi_tuftIB,mnaf_tuftIB,mnap_tuftIB,
     &  hnaf_tuftIB,mkdr_tuftIB,mka_tuftIB,
     &  hka_tuftIB,mk2_tuftIB,hk2_tuftIB,
     &  mkm_tuftIB,mkc_tuftIB,mkahp_tuftIB,
     &  mcat_tuftIB,hcat_tuftIB,mcal_tuftIB,
     &  mar_tuftIB,field_1mm       ,field_2mm       ,
     &  scale_tuftIB_gKAHP, scale_tuftIB_gNaP,
     &  scale_tuftIB_gKM  , scale_tuftIB_gKA, 
     &  scale_tuftIB_gCaL, scale_tuftIB_gKC,
     & rel_axonshift_tuftIB,gCaL_tuftIB,Mshift,
     & scale_tuftIB_gAR)

      ELSE if (nodecell(thisno).eq.'tuftRS   ') then
       CALL INTEGRATE_tuftRSXXB (O, time, num_tuftRS,
     &    V_tuftRS, curr_tuftRS,
     & initialize, firstcell, lastcell,
     & gAMPA_tuftRS, gNMDA_tuftRS, gGABA_A_tuftRS,
     & gGABA_B_tuftRS, Mg, 
     & gapcon_tuftRS,totaxgj_tuftRS,gjtable_tuftRS, dt,
     & totaxgj_tuft  , gjtable_tuft  , num_tuftIB   ,
c    & vax_tuftIB   ,
     & v_tuftIB   ,
     &  chi_tuftRS,mnaf_tuftRS,mnap_tuftRS,
     &  hnaf_tuftRS,mkdr_tuftRS,mka_tuftRS,
     &  hka_tuftRS,mk2_tuftRS,hk2_tuftRS,
     &  mkm_tuftRS,mkc_tuftRS,mkahp_tuftRS,
     &  mcat_tuftRS,hcat_tuftRS,mcal_tuftRS,
     &  mar_tuftRS,field_1mm       ,field_2mm       )

      ELSE if (nodecell(thisno).eq.'nontuftRS') then
       CALL INTEGRATE_nontuftRSXXB (O, time, num_nontuftRS,
     &    V_nontuftRS, curr_nontuftRS,
     &  initialize, firstcell, lastcell,
     & gAMPA_nontuftRS, gNMDA_nontuftRS, gGABA_A_nontuftRS,
     & gGABA_B_nontuftRS, Mg, 
     & gapcon_nontuftRS,totaxgj_nontuftRS,gjtable_nontuftRS, dt,
     &  chi_nontuftRS,mnaf_nontuftRS,mnap_nontuftRS,
     &  hnaf_nontuftRS,mkdr_nontuftRS,mka_nontuftRS,
     &  hka_nontuftRS,mk2_nontuftRS,hk2_nontuftRS,
     &  mkm_nontuftRS,mkc_nontuftRS,mkahp_nontuftRS,
     &  mcat_nontuftRS,hcat_nontuftRS,mcal_nontuftRS,
     &  mar_nontuftRS,field_1mm          ,field_2mm          ,
     &  nontuftRS_nFRB)

      ELSE if (nodecell(thisno).eq.'deepbask ') then
       CALL INTEGRATE_deepbaskx  (O, time, num_deepbask ,
     &    V_deepbask , curr_deepbask ,
     & initialize, firstcell, lastcell,
     & gAMPA_deepbask, gNMDA_deepbask, gGABA_A_deepbask,
     & Mg, 
     & gapcon_deepbask  ,totSDgj_deepbask   ,gjtable_deepbask, dt,
     &  chi_deepbask,mnaf_deepbask,mnap_deepbask,
     &  hnaf_deepbask,mkdr_deepbask,mka_deepbask,
     &  hka_deepbask,mk2_deepbask,hk2_deepbask,
     &  mkm_deepbask,mkc_deepbask,mkahp_deepbask,
     &  mcat_deepbask,hcat_deepbask,mcal_deepbask,
     &  mar_deepbask)

      ELSE if (nodecell(thisno).eq.'deepng   ') then
       CALL INTEGRATE_deepng     (O, time, num_deepng   ,
     &    V_deepng   , curr_deepng   ,
     & initialize, firstcell, lastcell,
     & gAMPA_deepng  , gNMDA_deepng  , gGABA_A_deepng  ,
     & Mg, 
     & gapcon_deepng    ,totSDgj_deepng     ,gjtable_deepng  , dt,
     &  chi_deepng  ,mnaf_deepng  ,mnap_deepng  ,
     &  hnaf_deepng  ,mkdr_deepng  ,mka_deepng  ,
     &  hka_deepng  ,mk2_deepng  ,hk2_deepng  ,
     &  mkm_deepng  ,mkc_deepng  ,mkahp_deepng  ,
     &  mcat_deepng  ,hcat_deepng  ,mcal_deepng  ,
     &  mar_deepng  )

      ELSE if (nodecell(thisno).eq.'deepaxax ') then
       CALL INTEGRATE_deepaxaxx (O, time, num_deepaxax ,
     &    V_deepaxax , curr_deepaxax ,
     & initialize, firstcell, lastcell,
     & gAMPA_deepaxax, gNMDA_deepaxax, gGABA_A_deepaxax,
     & Mg, 
     & gapcon_deepaxax  ,totSDgj_deepaxax   ,gjtable_deepaxax, dt,
     &  chi_deepaxax,mnaf_deepaxax,mnap_deepaxax,
     &  hnaf_deepaxax,mkdr_deepaxax,mka_deepaxax,
     &  hka_deepaxax,mk2_deepaxax,hk2_deepaxax,
     &  mkm_deepaxax,mkc_deepaxax,mkahp_deepaxax,
     &  mcat_deepaxax,hcat_deepaxax,mcal_deepaxax,
     &  mar_deepaxax)

      ELSE if (nodecell(thisno).eq.'deepLTS  ') then
       CALL INTEGRATE_deepLTSx  (O, time, num_deepLTS  ,
     &    V_deepLTS  , curr_deepLTS  ,
     & initialize, firstcell, lastcell,
     & gAMPA_deepLTS  , gNMDA_deepLTS  , gGABA_A_deepLTS  ,
     & Mg, 
     & gapcon_deepLTS  ,totSDgj_deepLTS  ,gjtable_deepLTS  , dt,
     &  chi_deepLTS,mnaf_deepLTS,mnap_deepLTS,
     &  hnaf_deepLTS,mkdr_deepLTS,mka_deepLTS,
     &  hka_deepLTS,mk2_deepLTS,hk2_deepLTS,
     &  mkm_deepLTS,mkc_deepLTS,mkahp_deepLTS,
     &  mcat_deepLTS,hcat_deepLTS,mcal_deepLTS,
     &  mar_deepLTS)

      ELSE if (nodecell(thisno).eq.'TCR      ') then
       CALL INTEGRATE_tcrxB      (O, time, num_tcr      ,
     &    V_tcr      , curr_tcr      ,
     & initialize, firstcell, lastcell,
     & gAMPA_tcr      , gNMDA_tcr      , gGABA_A_tcr      ,
     & gGABA_B_tcr, Mg, 
     & gapcon_tcr      ,totaxgj_tcr      ,gjtable_tcr      , dt,
     &  chi_tcr,mnaf_tcr,mnap_tcr,
     &  hnaf_tcr,mkdr_tcr,mka_tcr,
     &  hka_tcr,mk2_tcr,hk2_tcr,
     &  mkm_tcr,mkc_tcr,mkahp_tcr,
     &  mcat_tcr,hcat_tcr,mcal_tcr,
     &  mar_tcr)

      ELSE if (nodecell(thisno).eq.'nRT      ') then
       CALL INTEGRATE_nRTxB      (O, time, num_nRT      ,
     &    V_nRT      , curr_nRT      ,
     & initialize, firstcell, lastcell,
     & gAMPA_nRT      , gNMDA_nRT      , gGABA_A_nRT      ,
     & gGABA_B_nRT, Mg, 
     & gapcon_nRT      ,totSDgj_nRT      ,gjtable_nRT      , dt,
     &  chi_nRT,mnaf_nRT,mnap_nRT,
     &  hnaf_nRT,mkdr_nRT,mka_nRT,
     &  hka_nRT,mk2_nRT,hk2_nRT,
     &  mkm_nRT,mkc_nRT,mkahp_nRT,
     &  mcat_nRT,hcat_nRT,mcal_nRT,
     &  mar_nRT)

      ENDIF
c END INITIALIZATION OF INTEGRATION SUBROUTINES


c BEGIN guts of main program.
c Each node takes care of all the cells of a particular type.
c On a node: enumerate the cells of its type; calculate their
c  synaptic inputs; set applied currents, including those
c  required by ectopic generation; call the numerical integration
c  subroutine; set up the distal_axon vector.  Each node 
c  broadcasts its own distal_axon vector to all the others, and also
c  receives distal_axon vectors from all the others.
c Then, update outtime array and outctr vector.  Repeat.

1000    O = O + 1
        time = time + dt
        if (time.gt.timtot) goto 2000

c Define shift of tuftIB axonal gNa rate functions, & other axon shifts
       rel_axonshift_tuftIB = 5.0d0 + 0.0d0 * time/timtot
       rel_axonshift_suppyrRS = 5.d0                      
       rel_axonshift_suppyrFRB= 5.d0                      

! Calculate node-average of total tuftIB GABA-B per cell, & use it to
! control noisepe_tuftIB
        IF (nodecell(thisno) .eq. 'tuftIB   ') THEN
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_tuftIB  
          lastcell = firstcell - 1 + ncellspernode_tuftIB  
           z = 0.d0
           do L = firstcell, lastcell
           do i = 1, numcomp_tuftIB
            z = z + gGABA_B_tuftIB (i,L)
           end do
           end do
             z = z / dble(ncellspernode_tuftIB)
          if (z.le.10.d-3) then
            noisepe_tuftIB = 0.d0 * noisepe_tuftIB_save
          else if (z.le.20.d-3) then
      noisepe_tuftIB=0.d0 *noisepe_tuftIB_save*(1.d0-(z-10.d-3)/10.d-3)
          else
            noisepe_tuftIB = 0.d0
          endif
c          if (mod(O,500).eq.0) then
c            write(6,4908) thisno, noisepe_tuftIB
4908         format('thisno = ',i3,2x,F6.5)
c          endif
        ENDIF   

! Calculate node-average of total tuftRS GABA-B per cell, & use it to
! control noisepe_tuftRS
        IF (nodecell(thisno) .eq. 'tuftRS   ') THEN
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_tuftRS  
          lastcell = firstcell - 1 + ncellspernode_tuftRS  
           z = 0.d0
           do L = firstcell, lastcell
           do i = 1, numcomp_tuftRS
            z = z + gGABA_B_tuftRS (i,L)
           end do
           end do
             z = z / dble(ncellspernode_tuftRS)
          if (z.le.10.d-3) then
            noisepe_tuftRS = 0.d0 * noisepe_tuftRS_save
          else if (z.le.20.d-3) then
      noisepe_tuftRS=0.d0 *noisepe_tuftRS_save*(1.d0-(z-10.d-3)/10.d-3)
          else
            noisepe_tuftRS = 0.d0
          endif
        ENDIF   

       initialize = 1  ! so integration subroutines actually integrate

c Current pulses to selected TCR cells
!      if ((time.gt.300.d0).and.(time.le.310.d0)) then
!       curr_TCR(1,33) = 1.d0
!       curr_TCR(1,42) = 1.d0
!       curr_TCR(1,94) = 1.d0
!       curr_TCR(1,40) = 1.d0
!       curr_TCR(1,29) = 1.d0
!      else
!       curr_TCR(1,33) = 0.d0
!       curr_TCR(1,42) = 0.d0
!       curr_TCR(1,94) = 0.d0
!       curr_TCR(1,40) = 0.d0
!       curr_TCR(1,29) = 0.d0
!      endif

c      IF (THISNO.EQ.0) THEN
       IF (nodecell(thisno) .eq. 'suppyrRS ') THEN
c suppyrRS

c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_suppyrRS
          lastcell = firstcell - 1 + ncellspernode_suppyrRS

          IF (MOD(O,how_often).eq.0) then
c 1st set suppyrRS synaptic conductances to 0:

          do i = 1, numcomp_suppyrRS
!         do j = 1, num_suppyrRS
          do j = firstcell, lastcell ! Note
         gAMPA_suppyrRS(i,j)   = 0.d0
         gNMDA_suppyrRS(i,j)   = 0.d0
         gGABA_A_suppyrRS(i,j) = 0.d0
         gGABA_B_suppyrRS(i,j) = 0.d0
          end do
          end do

!        do L = 1, num_suppyrRS
         do L = firstcell, lastcell  ! Note

c Handle suppyrRS   -> suppyrRS
      do i = 1, num_suppyrRS_to_suppyrRS
       j = map_suppyrRS_to_suppyrRS(i,L) ! j = presynaptic cell
       k = com_suppyrRS_to_suppyrRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_suppyrRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_suppyrRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_suppyrRS_to_suppyrRS
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_suppyrRS(k,L)  = gAMPA_suppyrRS(k,L) +
     &  gAMPA_suppyrRS_to_suppyrRS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_suppyrRS(k,L) = gNMDA_suppyrRS(k,L) +
     &  gNMDA_suppyrRS_to_suppyrRS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_suppyrRS_to_suppyrRS
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_suppyrRS(k,L) = gNMDA_suppyrRS(k,L) +
     &  gNMDA_suppyrRS_to_suppyrRS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_suppyrRS_to_suppyrRS
       if (gNMDA_suppyrRS(k,L).gt.z)
     &  gNMDA_suppyrRS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i

c Handle suppyrFRB  -> suppyrRS
      do i = 1, num_suppyrFRB_to_suppyrRS
       j = map_suppyrFRB_to_suppyrRS(i,L) ! j = presynaptic cell
       k = com_suppyrFRB_to_suppyrRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_suppyrFRB(j)  ! enumerate presyn. spikes
        presyntime = outtime_suppyrFRB(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_suppyrFRB_to_suppyrRS
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_suppyrRS(k,L)  = gAMPA_suppyrRS(k,L) +
     &  gAMPA_suppyrFRB_to_suppyrRS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_suppyrRS(k,L) = gNMDA_suppyrRS(k,L) +
     &  gNMDA_suppyrFRB_to_suppyrRS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_suppyrFRB_to_suppyrRS
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_suppyrRS(k,L) = gNMDA_suppyrRS(k,L) +
     &  gNMDA_suppyrFRB_to_suppyrRS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_suppyrFRB_to_suppyrRS
       if (gNMDA_suppyrRS(k,L).gt.z)
     &  gNMDA_suppyrRS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle supbask    -> suppyrRS
      do i = 1, num_supbask_to_suppyrRS
       j = map_supbask_to_suppyrRS(i,L) ! j = presynaptic cell
       k = com_supbask_to_suppyrRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supbask(j)  ! enumerate presyn. spikes
        presyntime = outtime_supbask(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_supbask_to_suppyrRS
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_suppyrRS(k,L)  = gGABA_A_suppyrRS(k,L) +
     &  gGABA_supbask_to_suppyrRS * z      
! end GABA-A part

       end do ! m
      end do ! i

c Handle supng      -> suppyrRS
      do i = 1, num_supng_to_suppyrRS
       j = map_supng_to_suppyrRS(i,L) ! j = presynaptic cell
       k = com_supng_to_suppyrRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supng(j)  ! enumerate presyn. spikes
        presyntime = outtime_supng(m,j)
        delta = time - presyntime
        k0 = nint (10.d0 * delta) ! time, in units of 0.1 ms, to pass to otis_table
        if (k0 .gt. 50000) k = 50000  ! limit on size of otis_table

! GABA-A part AND GABA-B part
        dexparg = delta / tauGABA_supng_to_suppyrRS
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_suppyrRS(k,L)  = gGABA_A_suppyrRS(k,L) +
     &  gGABA_supng_to_suppyrRS * z      
! end GABA-A part

      gGABA_B_suppyrRS(k,L) = gGABA_B_suppyrRS(k,L) +
     &   gGABAB_supng_to_suppyrRS * otis_table(k0)
! end GABA-B part

       end do ! m
      end do ! i


c Handle supaxax    -> suppyrRS
      do i = 1, num_supaxax_to_suppyrRS
       j = map_supaxax_to_suppyrRS(i,L) ! j = presynaptic cell
       k = com_supaxax_to_suppyrRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supaxax(j)  ! enumerate presyn. spikes
        presyntime = outtime_supaxax(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_supaxax_to_suppyrRS
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_suppyrRS(k,L)  = gGABA_A_suppyrRS(k,L) +
     &  gGABA_supaxax_to_suppyrRS * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle supLTS     -> suppyrRS
      do i = 1, num_supLTS_to_suppyrRS
       j = map_supLTS_to_suppyrRS(i,L) ! j = presynaptic cell
       k = com_supLTS_to_suppyrRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supLTS(j)  ! enumerate presyn. spikes
        presyntime = outtime_supLTS(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_supLTS_to_suppyrRS
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_suppyrRS(k,L)  = gGABA_A_suppyrRS(k,L) +
     &  gGABA_supLTS_to_suppyrRS * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle spinstell  -> suppyrRS
      do i = 1, num_spinstell_to_suppyrRS
       j = map_spinstell_to_suppyrRS(i,L) ! j = presynaptic cell
       k = com_spinstell_to_suppyrRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_spinstell(j)  ! enumerate presyn. spikes
        presyntime = outtime_spinstell(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_spinstell_to_suppyrRS
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_suppyrRS(k,L)  = gAMPA_suppyrRS(k,L) +
     &  gAMPA_spinstell_to_suppyrRS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_suppyrRS(k,L) = gNMDA_suppyrRS(k,L) +
     &  gNMDA_spinstell_to_suppyrRS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_spinstell_to_suppyrRS
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_suppyrRS(k,L) = gNMDA_suppyrRS(k,L) +
     &  gNMDA_spinstell_to_suppyrRS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_spinstell_to_suppyrRS
       if (gNMDA_suppyrRS(k,L).gt.z)
     &  gNMDA_suppyrRS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle tuftIB     -> suppyrRS
      do i = 1, num_tuftIB_to_suppyrRS
       j = map_tuftIB_to_suppyrRS(i,L) ! j = presynaptic cell
       k = com_tuftIB_to_suppyrRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_tuftIB(j)  ! enumerate presyn. spikes
        presyntime = outtime_tuftIB(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_tuftIB_to_suppyrRS
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_suppyrRS(k,L)  = gAMPA_suppyrRS(k,L) +
     &  gAMPA_tuftIB_to_suppyrRS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_suppyrRS(k,L) = gNMDA_suppyrRS(k,L) +
     &  gNMDA_tuftIB_to_suppyrRS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_tuftIB_to_suppyrRS
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_suppyrRS(k,L) = gNMDA_suppyrRS(k,L) +
     &  gNMDA_tuftIB_to_suppyrRS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_tuftIB_to_suppyrRS
       if (gNMDA_suppyrRS(k,L).gt.z)
     &  gNMDA_suppyrRS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle tuftRS     -> suppyrRS
      do i = 1, num_tuftRS_to_suppyrRS
       j = map_tuftRS_to_suppyrRS(i,L) ! j = presynaptic cell
       k = com_tuftRS_to_suppyrRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_tuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_tuftRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_tuftRS_to_suppyrRS
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_suppyrRS(k,L)  = gAMPA_suppyrRS(k,L) +
     &  gAMPA_tuftRS_to_suppyrRS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_suppyrRS(k,L) = gNMDA_suppyrRS(k,L) +
     &  gNMDA_tuftRS_to_suppyrRS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_tuftRS_to_suppyrRS
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_suppyrRS(k,L) = gNMDA_suppyrRS(k,L) +
     &  gNMDA_tuftRS_to_suppyrRS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_tuftRS_to_suppyrRS
       if (gNMDA_suppyrRS(k,L).gt.z)
     &  gNMDA_suppyrRS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle deepaxax   -> suppyrRS
      do i = 1, num_deepaxax_to_suppyrRS
       j = map_deepaxax_to_suppyrRS(i,L) ! j = presynaptic cell
       k = com_deepaxax_to_suppyrRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepaxax(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepaxax(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepaxax_to_suppyrRS
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_suppyrRS(k,L)  = gGABA_A_suppyrRS(k,L) +
     &  gGABA_deepaxax_to_suppyrRS * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle deepLTS    -> suppyrRS
      do i = 1, num_deepLTS_to_suppyrRS
       j = map_deepLTS_to_suppyrRS(i,L) ! j = presynaptic cell
       k = com_deepLTS_to_suppyrRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepLTS(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepLTS(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepLTS_to_suppyrRS
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_suppyrRS(k,L)  = gGABA_A_suppyrRS(k,L) +
     &  gGABA_deepLTS_to_suppyrRS * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle TCR        -> suppyrRS
      do i = 1, num_TCR_to_suppyrRS
       j = map_TCR_to_suppyrRS(i,L) ! j = presynaptic cell
       k = com_TCR_to_suppyrRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_TCR(j)  ! enumerate presyn. spikes
        presyntime = outtime_TCR(m,j)
        delta = time - presyntime - thal_cort_delay

         IF (DELTA.GE.0.d0) THEN
! AMPA part
        dexparg = delta / tauAMPA_TCR_to_suppyrRS
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_suppyrRS(k,L)  = gAMPA_suppyrRS(k,L) +
     &  gAMPA_TCR_to_suppyrRS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_suppyrRS(k,L) = gNMDA_suppyrRS(k,L) +
     &  gNMDA_TCR_to_suppyrRS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_TCR_to_suppyrRS
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_suppyrRS(k,L) = gNMDA_suppyrRS(k,L) +
     &  gNMDA_TCR_to_suppyrRS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_TCR_to_suppyrRS
       if (gNMDA_suppyrRS(k,L).gt.z)
     &  gNMDA_suppyrRS(k,L) = z
! end NMDA part

        ENDIF  ! condition for checking that delta >= 0.
       end do ! m
      end do ! i


c Handle nontuftRS  -> suppyrRS
      do i = 1, num_nontuftRS_to_suppyrRS
       j = map_nontuftRS_to_suppyrRS(i,L) ! j = presynaptic cell
       k = com_nontuftRS_to_suppyrRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_nontuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_nontuftRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_nontuftRS_to_suppyrRS
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_suppyrRS(k,L)  = gAMPA_suppyrRS(k,L) +
     &  gAMPA_nontuftRS_to_suppyrRS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_suppyrRS(k,L) = gNMDA_suppyrRS(k,L) +
     &  gNMDA_nontuftRS_to_suppyrRS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_nontuftRS_to_suppyrRS
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_suppyrRS(k,L) = gNMDA_suppyrRS(k,L) +
     &  gNMDA_nontuftRS_to_suppyrRS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_nontuftRS_to_suppyrRS
       if (gNMDA_suppyrRS(k,L).gt.z)
     &  gNMDA_suppyrRS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i

         end do
c End enumeration of suppyrRS
       ENDIF ! if (mod(O,how_often).eq.0)...

! Define phasic currents to suppyrRS cells, ectopic spikes,
! tonic synaptic conductances

      if (mod(O,200).eq.0) then
       call durand(seed,num_suppyrRS,ranvec_suppyrRS) 
!       do L = 1, num_suppyrRS
        do L = firstcell, lastcell  ! Note
         if ((ranvec_suppyrRS(L).gt.0.d0).and.
     &     (ranvec_suppyrRS(L).le.noisepe_suppyrRS)) then
          curr_suppyrRS(72,L) = 0.4d0
          ectr_suppyrRS = ectr_suppyrRS + 1
         else
          curr_suppyrRS(72,L) = 0.d0
         endif 
        end do
      endif


! Call integration routine for suppyrRS cells
       CALL INTEGRATE_suppyrRSXPB (O, time, num_suppyrRS,
     &    V_suppyrRS, curr_suppyrRS,
     &    initialize, firstcell, lastcell,
     & gAMPA_suppyrRS, gNMDA_suppyrRS, gGABA_A_suppyrRS,
     & gGABA_B_suppyrRS, Mg, 
     & gapcon_suppyrRS  ,totaxgj_suppyrRS   ,gjtable_suppyrRS, dt,
     & totaxgj_suppyr, gjtable_suppyr, num_suppyrFRB,
c    & vax_suppyrFRB,
     & v_suppyrFRB,
     &  chi_suppyrRS,mnaf_suppyrRS,mnap_suppyrRS,
     &  hnaf_suppyrRS,mkdr_suppyrRS,mka_suppyrRS,
     &  hka_suppyrRS,mk2_suppyrRS,hk2_suppyrRS,
     &  mkm_suppyrRS,mkc_suppyrRS,mkahp_suppyrRS,
     &  mcat_suppyrRS,hcat_suppyrRS,mcal_suppyrRS,
     &  mar_suppyrRS,field_1mm ,field_2mm, rel_axonshift_suppyrRS)

       IF (mod(O,5).eq.0) then
! Set up axonal gj voltage array and broadcast it to node 1
! (FRB cells) and receive FRB array - for mixed gj.
!      do L = 1, num_suppyrRS
!       vax_suppyrRS (L) = V_suppyrRS (74,L)
!      end do
!c RE-DO ALL THIS!!
!     call mpi_bcast (vax_suppyrRS  ,num_suppyrRS,
!    &    mpi_double_precision, 0, mpi_comm_world, info)
!     call mpi_bcast (vax_suppyrFRB ,num_suppyrFRB,
!    &    mpi_double_precision, 1, mpi_comm_world, info)
!     call mpi_bcast (vax_tuftIB    ,num_tuftIB  ,
!    &    mpi_double_precision, 6, mpi_comm_world, info)
!     call mpi_bcast (vax_tuftRS    ,num_tuftRS   ,
!    &    mpi_double_precision, 7, mpi_comm_world, info)

       do L = firstcell, lastcell
            k = table_axgjcompallow_suppyrRS(1)
            gj_axon_suppyrRS (L-firstcell+1) = V_suppyrRS (k,L)
       end do
  
           call mpi_allgather (    gj_axon_suppyrRS,
     &  maxcellspernode, mpi_double_precision,
     &      gj_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

      ENDIF ! vax set-up, broadcasting and receiving
  

       IF (mod(O,how_often).eq.0) then
! Set up distal axon voltage array and broadcast it.
! also field data                                     
c      do L = 1, num_suppyrRS
       do L = firstcell, lastcell
        distal_axon_suppyrRS (L-firstcell+1) = V_suppyrRS (72,L)
       end do
  
           call mpi_allgather (distal_axon_suppyrRS,
     &  maxcellspernode, mpi_double_precision,
     &  distal_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

        field_1mm_local(1) = field_1mm
        field_2mm_local(1) = field_2mm
           call mpi_allgather (field_1mm_local,     
     &  1              , mpi_double_precision,
     &  field_1mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
           call mpi_allgather (field_2mm_local,     
     &  1              , mpi_double_precision,
     &  field_2mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

        ENDIF ! if (mod(O,how_often).eq.0) ....

          if (mod(O,250).eq.0) then ! write voltages to sysprint
c     write(6,213) time,
c    & ldistal_axon_suppyrRS  (1), 
c    & ldistal_axon_suppyrRS (num_suppyrRS),
c    & ldistal_axon_suppyrFRB (1),
c    & ldistal_axon_suppyrFRB(num_suppyrFRB),
c    & ldistal_axon_supbask   (1),
c    & ldistal_axon_supbask  (num_supbask ),
c    & ldistal_axon_supaxax   (1),
c    & ldistal_axon_supaxax  (num_supaxax  ) 
c     write(6,213) time,
c    & ldistal_axon_supLTS    (1),
c    & ldistal_axon_supLTS   (num_supLTS   ),
c    & ldistal_axon_spinstell (1),
c    & ldistal_axon_spinstell(num_spinstell),
c    & ldistal_axon_tuftIB    (1),
c    & ldistal_axon_tuftIB   (num_tuftIB   ) 
c     write(6,213) time,
c    & ldistal_axon_tuftRS    (1),
c    & ldistal_axon_tuftRS   (num_tuftRS   ),
c    & ldistal_axon_nontuftRS (1),
c    & ldistal_axon_nontuftRS(num_nontuftRS),
c    & ldistal_axon_deepbask  (1),
c    & ldistal_axon_deepbask (num_deepbask ) 
c     write(6,213) time,
c    & ldistal_axon_deepaxax  (1),
c    & ldistal_axon_deepaxax (num_deepaxax ),
c    & ldistal_axon_deepLTS   (1),
c    & ldistal_axon_deepLTS  (num_deepLTS  ),
c    & ldistal_axon_TCR       (1),
c    & ldistal_axon_TCR      (num_TCR      ),
c    & ldistal_axon_nRT       (1),
c    & ldistal_axon_nRT      (num_nRT      ) 
213    FORMAT(f7.2,8f5.0)
          endif ! end writing to sysprint



! END thisno for suppyrRS

c      ELSE IF (THISNO.EQ.1) THEN
       ELSE IF (nodecell(thisno) .eq. 'suppyrFRB') THEN
c suppyrFRB

c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_suppyrFRB
          lastcell = firstcell - 1 + ncellspernode_suppyrFRB

         IF (MOD(O,how_often).eq.0) then
c 1st set suppyrFRB synaptic conductances to 0:

          do i = 1, numcomp_suppyrFRB
c         do j = 1, num_suppyrFRB
          do j = firstcell, lastcell
         gAMPA_suppyrFRB(i,j)   = 0.d0 
         gNMDA_suppyrFRB(i,j)   = 0.d0
         gGABA_A_suppyrFRB(i,j) = 0.d0
         gGABA_B_suppyrFRB(i,j) = 0.d0
          end do
          end do

         do L = firstcell, lastcell
c Handle suppyrRS   -> suppyrFRB
      do i = 1, num_suppyrRS_to_suppyrFRB
       j = map_suppyrRS_to_suppyrFRB(i,L) ! j = presynaptic cell
       k = com_suppyrRS_to_suppyrFRB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_suppyrRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_suppyrRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_suppyrRS_to_suppyrFRB
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_suppyrFRB(k,L)  = gAMPA_suppyrFRB(k,L) +
     &  gAMPA_suppyrRS_to_suppyrFRB * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_suppyrFRB(k,L) = gNMDA_suppyrFRB(k,L) +
     &  gNMDA_suppyrRS_to_suppyrFRB * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_suppyrRS_to_suppyrFRB
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_suppyrFRB(k,L) = gNMDA_suppyrFRB(k,L) +
     &  gNMDA_suppyrRS_to_suppyrFRB * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_suppyrRS_to_suppyrFRB
       if (gNMDA_suppyrFRB(k,L).gt.z)
     &  gNMDA_suppyrFRB(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle suppyrFRB  -> suppyrFRB
      do i = 1, num_suppyrFRB_to_suppyrFRB
       j = map_suppyrFRB_to_suppyrFRB(i,L) ! j = presynaptic cell
       k = com_suppyrFRB_to_suppyrFRB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_suppyrFRB(j)  ! enumerate presyn. spikes
        presyntime = outtime_suppyrFRB(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_suppyrFRB_to_suppyrFRB
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_suppyrFRB(k,L)  = gAMPA_suppyrFRB(k,L) +
     &  gAMPA_suppyrFRB_to_suppyrFRB * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_suppyrFRB(k,L) = gNMDA_suppyrFRB(k,L) +
     &  gNMDA_suppyrFRB_to_suppyrFRB * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_suppyrFRB_to_suppyrFRB
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_suppyrFRB(k,L) = gNMDA_suppyrFRB(k,L) +
     &  gNMDA_suppyrFRB_to_suppyrFRB * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_suppyrFRB_to_suppyrFRB
       if (gNMDA_suppyrFRB(k,L).gt.z)
     &  gNMDA_suppyrFRB(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle supbask    -> suppyrFRB
      do i = 1, num_supbask_to_suppyrFRB
       j = map_supbask_to_suppyrFRB(i,L) ! j = presynaptic cell
       k = com_supbask_to_suppyrFRB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supbask(j)  ! enumerate presyn. spikes
        presyntime = outtime_supbask(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_supbask_to_suppyrFRB
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_suppyrFRB(k,L)  = gGABA_A_suppyrFRB(k,L) +
     &  gGABA_supbask_to_suppyrFRB * z      
! end GABA-A part

       end do ! m
      end do ! i

c Handle supng      -> suppyrFRB
      do i = 1, num_supng_to_suppyrFRB
       j = map_supng_to_suppyrFRB(i,L) ! j = presynaptic cell
       k = com_supng_to_suppyrFRB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supng(j)  ! enumerate presyn. spikes
        presyntime = outtime_supng(m,j)
        delta = time - presyntime
        k0 = nint (10.d0 * delta) ! time, in units of 0.1 ms, to pass to otis_table
        if (k0 .gt. 50000) k = 50000  ! limit on size of otis_table

! GABA-A part AND GABA-B part
        dexparg = delta / tauGABA_supng_to_suppyrFRB
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_suppyrFRB(k,L)  = gGABA_A_suppyrFRB(k,L) +
     &  gGABA_supng_to_suppyrFRB * z      
! end GABA-A part

      gGABA_B_suppyrFRB(k,L) = gGABA_B_suppyrFRB(k,L) +
     &   gGABAB_supng_to_suppyrFRB * otis_table(k0)
! end GABA-B part

       end do ! m
      end do ! i



c Handle supaxax    -> suppyrFRB
      do i = 1, num_supaxax_to_suppyrFRB
       j = map_supaxax_to_suppyrFRB(i,L) ! j = presynaptic cell
       k = com_supaxax_to_suppyrFRB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supaxax(j)  ! enumerate presyn. spikes
        presyntime = outtime_supaxax(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_supaxax_to_suppyrFRB
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_suppyrFRB(k,L)  = gGABA_A_suppyrFRB(k,L) +
     &  gGABA_supaxax_to_suppyrFRB * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle supLTS     -> suppyrFRB
      do i = 1, num_supLTS_to_suppyrFRB
       j = map_supLTS_to_suppyrFRB(i,L) ! j = presynaptic cell
       k = com_supLTS_to_suppyrFRB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supLTS(j)  ! enumerate presyn. spikes
        presyntime = outtime_supLTS(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_supLTS_to_suppyrFRB
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_suppyrFRB(k,L)  = gGABA_A_suppyrFRB(k,L) +
     &  gGABA_supLTS_to_suppyrFRB * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle spinstell  -> suppyrFRB
      do i = 1, num_spinstell_to_suppyrFRB
       j = map_spinstell_to_suppyrFRB(i,L) ! j = presynaptic cell
       k = com_spinstell_to_suppyrFRB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_spinstell(j)  ! enumerate presyn. spikes
        presyntime = outtime_spinstell(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_spinstell_to_suppyrFRB
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_suppyrFRB(k,L)  = gAMPA_suppyrFRB(k,L) +
     &  gAMPA_spinstell_to_suppyrFRB * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_suppyrFRB(k,L) = gNMDA_suppyrFRB(k,L) +
     &  gNMDA_spinstell_to_suppyrFRB * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_spinstell_to_suppyrFRB
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_suppyrFRB(k,L) = gNMDA_suppyrFRB(k,L) +
     &  gNMDA_spinstell_to_suppyrFRB * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_spinstell_to_suppyrFRB
       if (gNMDA_suppyrFRB(k,L).gt.z)
     &  gNMDA_suppyrFRB(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle tuftIB     -> suppyrFRB
      do i = 1, num_tuftIB_to_suppyrFRB
       j = map_tuftIB_to_suppyrFRB(i,L) ! j = presynaptic cell
       k = com_tuftIB_to_suppyrFRB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_tuftIB(j)  ! enumerate presyn. spikes
        presyntime = outtime_tuftIB(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_tuftIB_to_suppyrFRB
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_suppyrFRB(k,L)  = gAMPA_suppyrFRB(k,L) +
     &  gAMPA_tuftIB_to_suppyrFRB * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_suppyrFRB(k,L) = gNMDA_suppyrFRB(k,L) +
     &  gNMDA_tuftIB_to_suppyrFRB * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_tuftIB_to_suppyrFRB
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_suppyrFRB(k,L) = gNMDA_suppyrFRB(k,L) +
     &  gNMDA_tuftIB_to_suppyrFRB * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_tuftIB_to_suppyrFRB
       if (gNMDA_suppyrFRB(k,L).gt.z)
     &  gNMDA_suppyrFRB(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle tuftRS     -> suppyrFRB
      do i = 1, num_tuftRS_to_suppyrFRB
       j = map_tuftRS_to_suppyrFRB(i,L) ! j = presynaptic cell
       k = com_tuftRS_to_suppyrFRB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_tuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_tuftRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_tuftRS_to_suppyrFRB
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_suppyrFRB(k,L)  = gAMPA_suppyrFRB(k,L) +
     &  gAMPA_tuftRS_to_suppyrFRB * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_suppyrFRB(k,L) = gNMDA_suppyrFRB(k,L) +
     &  gNMDA_tuftRS_to_suppyrFRB * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_tuftRS_to_suppyrFRB
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_suppyrFRB(k,L) = gNMDA_suppyrFRB(k,L) +
     &  gNMDA_tuftRS_to_suppyrFRB * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_tuftRS_to_suppyrFRB
       if (gNMDA_suppyrFRB(k,L).gt.z)
     &  gNMDA_suppyrFRB(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle deepaxax   -> suppyrFRB
      do i = 1, num_deepaxax_to_suppyrFRB
       j = map_deepaxax_to_suppyrFRB(i,L) ! j = presynaptic cell
       k = com_deepaxax_to_suppyrFRB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepaxax(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepaxax(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepaxax_to_suppyrFRB
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_suppyrFRB(k,L)  = gGABA_A_suppyrFRB(k,L) +
     &  gGABA_deepaxax_to_suppyrFRB * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle deepLTS    -> suppyrFRB
      do i = 1, num_deepLTS_to_suppyrFRB
       j = map_deepLTS_to_suppyrFRB(i,L) ! j = presynaptic cell
       k = com_deepLTS_to_suppyrFRB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepLTS(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepLTS(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepLTS_to_suppyrFRB
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_suppyrFRB(k,L)  = gGABA_A_suppyrFRB(k,L) +
     &  gGABA_deepLTS_to_suppyrFRB * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle TCR        -> suppyrFRB
      do i = 1, num_TCR_to_suppyrFRB
       j = map_TCR_to_suppyrFRB(i,L) ! j = presynaptic cell
       k = com_TCR_to_suppyrFRB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_TCR(j)  ! enumerate presyn. spikes
        presyntime = outtime_TCR(m,j)
        delta = time - presyntime - thal_cort_delay

         IF (DELTA.GE.0.d0) THEN
! AMPA part
        dexparg = delta / tauAMPA_TCR_to_suppyrFRB
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_suppyrFRB(k,L)  = gAMPA_suppyrFRB(k,L) +
     &  gAMPA_TCR_to_suppyrFRB * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_suppyrFRB(k,L) = gNMDA_suppyrFRB(k,L) +
     &  gNMDA_TCR_to_suppyrFRB * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_TCR_to_suppyrFRB
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_suppyrFRB(k,L) = gNMDA_suppyrFRB(k,L) +
     &  gNMDA_TCR_to_suppyrFRB * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_TCR_to_suppyrFRB
       if (gNMDA_suppyrFRB(k,L).gt.z)
     &  gNMDA_suppyrFRB(k,L) = z
! end NMDA part

        ENDIF  ! condition for checking that delta >= 0.
       end do ! m
      end do ! i


c Handle nontuftRS  -> suppyrFRB
      do i = 1, num_nontuftRS_to_suppyrFRB
       j = map_nontuftRS_to_suppyrFRB(i,L) ! j = presynaptic cell
       k = com_nontuftRS_to_suppyrFRB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_nontuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_nontuftRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_nontuftRS_to_suppyrFRB
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_suppyrFRB(k,L)  = gAMPA_suppyrFRB(k,L) +
     &  gAMPA_nontuftRS_to_suppyrFRB * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_suppyrFRB(k,L) = gNMDA_suppyrFRB(k,L) +
     &  gNMDA_nontuftRS_to_suppyrFRB * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_nontuftRS_to_suppyrFRB
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_suppyrFRB(k,L) = gNMDA_suppyrFRB(k,L) +
     &  gNMDA_nontuftRS_to_suppyrFRB * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_nontuftRS_to_suppyrFRB
       if (gNMDA_suppyrFRB(k,L).gt.z)
     &  gNMDA_suppyrFRB(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


         end do
c End enumeration of suppyrFRB
         ENDIF ! if (mod(O,how_often).eq.0)...

! Define currents to suppyrFRB cells, ectopic spikes,
! tonic synaptic conductances

      if (mod(O,200).eq.0) then
       call durand(seed,num_suppyrFRB,ranvec_suppyrFRB) 
        do L = firstcell, lastcell
         if ((ranvec_suppyrFRB(L).gt.0.d0).and.
     &     (ranvec_suppyrFRB(L).le.noisepe_suppyrFRB)) then
          curr_suppyrFRB(72,L) = 0.4d0
          ectr_suppyrFRB = ectr_suppyrFRB + 1
         else
          curr_suppyrFRB(72,L) = 0.d0
         endif 
        end do
      endif

! Call integration routine for suppyrFRB cells
       CALL INTEGRATE_suppyrFRBxPB (O, time, num_suppyrFRB,
     &    V_suppyrFRB, curr_suppyrFRB,
     &    initialize, firstcell, lastcell, 
     & gAMPA_suppyrFRB, gNMDA_suppyrFRB, gGABA_A_suppyrFRB,
     & gGABA_B_suppyrFRB, Mg, 
     & gapcon_suppyrFRB ,totaxgj_suppyrFRB  ,gjtable_suppyrFRB, dt,
     & totaxgj_suppyr, gjtable_suppyr, num_suppyrRS,
c    & vax_suppyrRS,
     & v_suppyrRS,
     &  chi_suppyrFRB,mnaf_suppyrFRB,mnap_suppyrFRB,
     &  hnaf_suppyrFRB,mkdr_suppyrFRB,mka_suppyrFRB,
     &  hka_suppyrFRB,mk2_suppyrFRB,hk2_suppyrFRB,
     &  mkm_suppyrFRB,mkc_suppyrFRB,mkahp_suppyrFRB,
     &  mcat_suppyrFRB,hcat_suppyrFRB,mcal_suppyrFRB,
     &  mar_suppyrFRB,field_1mm ,field_2mm, rel_axonshift_suppyrFRB,
     &  scale_suppyrFRB_gNaP)

       IF (mod(O,5).eq.0) then
! Set up axonal gj voltage array and broadcast it to node 0
! (RS cells) and receive RS array - for mixed gj.
!      do L = 1, num_suppyrFRB
!       vax_suppyrFRB (L) = V_suppyrFRB (74,L)
!      end do

!     call mpi_bcast (vax_suppyrRS  ,num_suppyrRS,
!    &    mpi_double_precision, 0, mpi_comm_world, info)
!     call mpi_bcast (vax_suppyrFRB ,num_suppyrFRB,
!    &    mpi_double_precision, 1, mpi_comm_world, info)
!     call mpi_bcast (vax_tuftIB    ,num_tuftIB  ,
!    &    mpi_double_precision, 6, mpi_comm_world, info)
!     call mpi_bcast (vax_tuftRS    ,num_tuftRS   ,
!    &    mpi_double_precision, 7, mpi_comm_world, info)

       do L = firstcell, lastcell
            k = table_axgjcompallow_suppyrFRB(1)
            gj_axon_suppyrFRB(L-firstcell+1) = V_suppyrFRB(k,L)
       end do
  
           call mpi_allgather (    gj_axon_suppyrFRB,
     &  maxcellspernode, mpi_double_precision,
     &      gj_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

      ENDIF ! vax set-up, broadcasting and receiving
  

       IF (mod(O,how_often).eq.0) then
! Set up distal axon voltage array and broadcast it.
c      do L = 1, num_suppyrFRB
       do L = firstcell, lastcell
        distal_axon_suppyrFRB (L-firstcell+1) = V_suppyrFRB (72,L)
       end do
  
           call mpi_allgather (distal_axon_suppyrFRB,
     &  maxcellspernode, mpi_double_precision,
     &  distal_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

        field_1mm_local(1) = field_1mm
        field_2mm_local(1) = field_2mm
           call mpi_allgather (field_1mm_local,     
     &  1              , mpi_double_precision,
     &  field_1mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
           call mpi_allgather (field_2mm_local,     
     &  1              , mpi_double_precision,
     &  field_2mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
                        
        ENDIF ! if (mod(O,how_often).eq.0) ....

! END thisno for suppyrFRB

c      ELSE IF (THISNO.EQ.2) THEN
       ELSE IF (nodecell(thisno) .eq. 'supbask  ') THEN
c supbask

c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_supbask 
          lastcell = firstcell - 1 + ncellspernode_supbask 

        IF (mod(O,how_often).eq.0) then
c 1st set supbask synaptic conductances to 0:

          do i = 1, numcomp_supbask
          do j = firstcell, lastcell
         gAMPA_supbask(i,j)     = 0.d0
         gNMDA_supbask(i,j)     = 0.d0
         gGABA_A_supbask(i,j)   = 0.d0
          end do
          end do

         do L = firstcell, lastcell
c Handle suppyrRS   -> supbask
      do i = 1, num_suppyrRS_to_supbask  
       j = map_suppyrRS_to_supbask(i,L) ! j = presynaptic cell
       k = com_suppyrRS_to_supbask(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_suppyrRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_suppyrRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_suppyrRS_to_supbask  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_supbask(k,L)  = gAMPA_supbask(k,L) +
     &  gAMPA_suppyrRS_to_supbask * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_supbask(k,L) = gNMDA_supbask(k,L) +
     &  gNMDA_suppyrRS_to_supbask * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_suppyrRS_to_supbask  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_supbask(k,L) = gNMDA_supbask(k,L) +
     &  gNMDA_suppyrRS_to_supbask * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_suppyrRS_to_supbask  
       if (gNMDA_supbask(k,L).gt.z)
     &  gNMDA_supbask(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle suppyrFRB  -> supbask
      do i = 1, num_suppyrFRB_to_supbask  
       j = map_suppyrFRB_to_supbask(i,L) ! j = presynaptic cell
       k = com_suppyrFRB_to_supbask(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_suppyrFRB(j)  ! enumerate presyn. spikes
        presyntime = outtime_suppyrFRB(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_suppyrFRB_to_supbask  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_supbask(k,L)  = gAMPA_supbask(k,L) +
     &  gAMPA_suppyrFRB_to_supbask * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_supbask(k,L) = gNMDA_supbask(k,L) +
     &  gNMDA_suppyrFRB_to_supbask * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_suppyrFRB_to_supbask  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_supbask(k,L) = gNMDA_supbask(k,L) +
     &  gNMDA_suppyrFRB_to_supbask * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_suppyrFRB_to_supbask  
       if (gNMDA_supbask(k,L).gt.z)
     &  gNMDA_supbask(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle supbask    -> supbask
      do i = 1, num_supbask_to_supbask  
       j = map_supbask_to_supbask(i,L) ! j = presynaptic cell
       k = com_supbask_to_supbask(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supbask(j)  ! enumerate presyn. spikes
        presyntime = outtime_supbask(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_supbask_to_supbask  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_supbask(k,L)  = gGABA_A_supbask(k,L) +
     &  gGABA_supbask_to_supbask * z      
! end GABA-A part

       end do ! m
      end do ! i

c Handle supng      -> supbask 
      do i = 1, num_supng_to_supbask 
       j = map_supng_to_supbask (i,L) ! j = presynaptic cell
       k = com_supng_to_supbask (i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supng(j)  ! enumerate presyn. spikes
        presyntime = outtime_supng(m,j)
        delta = time - presyntime

! GABA-A part AND GABA-B part
        dexparg = delta / tauGABA_supng_to_supbask 
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_supbask (k,L)  = gGABA_A_supbask (k,L) +
     &  gGABA_supng_to_supbask  * z      
! end GABA-A part

       end do ! m
      end do ! i



c Handle supLTS     -> supbask
      do i = 1, num_supLTS_to_supbask  
       j = map_supLTS_to_supbask(i,L) ! j = presynaptic cell
       k = com_supLTS_to_supbask(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supLTS(j)  ! enumerate presyn. spikes
        presyntime = outtime_supLTS(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_supLTS_to_supbask  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_supbask(k,L)  = gGABA_A_supbask(k,L) +
     &  gGABA_supLTS_to_supbask * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle spinstell  -> supbask
      do i = 1, num_spinstell_to_supbask  
       j = map_spinstell_to_supbask(i,L) ! j = presynaptic cell
       k = com_spinstell_to_supbask(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_spinstell(j)  ! enumerate presyn. spikes
        presyntime = outtime_spinstell(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_spinstell_to_supbask  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_supbask(k,L)  = gAMPA_supbask(k,L) +
     &  gAMPA_spinstell_to_supbask * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_supbask(k,L) = gNMDA_supbask(k,L) +
     &  gNMDA_spinstell_to_supbask * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_spinstell_to_supbask  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_supbask(k,L) = gNMDA_supbask(k,L) +
     &  gNMDA_spinstell_to_supbask * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_spinstell_to_supbask  
       if (gNMDA_supbask(k,L).gt.z)
     &  gNMDA_supbask(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle tuftIB     -> supbask
      do i = 1, num_tuftIB_to_supbask  
       j = map_tuftIB_to_supbask(i,L) ! j = presynaptic cell
       k = com_tuftIB_to_supbask(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_tuftIB(j)  ! enumerate presyn. spikes
        presyntime = outtime_tuftIB(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_tuftIB_to_supbask  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_supbask(k,L)  = gAMPA_supbask(k,L) +
     &  gAMPA_tuftIB_to_supbask * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_supbask(k,L) = gNMDA_supbask(k,L) +
     &  gNMDA_tuftIB_to_supbask * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_tuftIB_to_supbask  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_supbask(k,L) = gNMDA_supbask(k,L) +
     &  gNMDA_tuftIB_to_supbask * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_tuftIB_to_supbask  
       if (gNMDA_supbask(k,L).gt.z)
     &  gNMDA_supbask(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle tuftRS     -> supbask
      do i = 1, num_tuftRS_to_supbask  
       j = map_tuftRS_to_supbask(i,L) ! j = presynaptic cell
       k = com_tuftRS_to_supbask(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_tuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_tuftRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_tuftRS_to_supbask  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_supbask(k,L)  = gAMPA_supbask(k,L) +
     &  gAMPA_tuftRS_to_supbask * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_supbask(k,L) = gNMDA_supbask(k,L) +
     &  gNMDA_tuftRS_to_supbask * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_tuftRS_to_supbask  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_supbask(k,L) = gNMDA_supbask(k,L) +
     &  gNMDA_tuftRS_to_supbask * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_tuftRS_to_supbask  
       if (gNMDA_supbask(k,L).gt.z)
     &  gNMDA_supbask(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle deepLTS    -> supbask
      do i = 1, num_deepLTS_to_supbask  
       j = map_deepLTS_to_supbask(i,L) ! j = presynaptic cell
       k = com_deepLTS_to_supbask(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepLTS(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepLTS(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepLTS_to_supbask  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_supbask(k,L)  = gGABA_A_supbask(k,L) +
     &  gGABA_deepLTS_to_supbask * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle deepTCR    -> supbask
      do i = 1, num_TCR_to_supbask  
       j = map_TCR_to_supbask(i,L) ! j = presynaptic cell
       k = com_TCR_to_supbask(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_TCR(j)  ! enumerate presyn. spikes
        presyntime = outtime_TCR(m,j)
        delta = time - presyntime - thal_cort_delay

         IF (DELTA.GE.0.d0) THEN
! AMPA part
        dexparg = delta / tauAMPA_TCR_to_supbask  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_supbask(k,L)  = gAMPA_supbask(k,L) +
     &  gAMPA_TCR_to_supbask * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_supbask(k,L) = gNMDA_supbask(k,L) +
     &  gNMDA_TCR_to_supbask * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_TCR_to_supbask  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_supbask(k,L) = gNMDA_supbask(k,L) +
     &  gNMDA_TCR_to_supbask * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_TCR_to_supbask  
       if (gNMDA_supbask(k,L).gt.z)
     &  gNMDA_supbask(k,L) = z
! end NMDA part

        ENDIF  ! condition for checking that delta >= 0.
       end do ! m
      end do ! i


c Handle nontuftRS  -> supbask
      do i = 1, num_nontuftRS_to_supbask  
       j = map_nontuftRS_to_supbask(i,L) ! j = presynaptic cell
       k = com_nontuftRS_to_supbask(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_nontuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_nontuftRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_nontuftRS_to_supbask  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_supbask(k,L)  = gAMPA_supbask(k,L) +
     &  gAMPA_nontuftRS_to_supbask * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_supbask(k,L) = gNMDA_supbask(k,L) +
     &  gNMDA_nontuftRS_to_supbask * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_nontuftRS_to_supbask  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_supbask(k,L) = gNMDA_supbask(k,L) +
     &  gNMDA_nontuftRS_to_supbask * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_nontuftRS_to_supbask  
       if (gNMDA_supbask(k,L).gt.z)
     &  gNMDA_supbask(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


         end do
c End enumeration of supbask  
        ENDIF  ! if (mod(O,how_often).eq.0) ....

! Define currents to supbask   cells, ectopic spikes,
! tonic synaptic conductances

! Call integration routine for supbask   cells
       CALL INTEGRATE_supbaskx (O, time, num_supbask ,
     &    V_supbask , curr_supbask ,
     $    initialize, firstcell, lastcell,
     & gAMPA_supbask , gNMDA_supbask , gGABA_A_supbask ,
     & Mg, 
     & gapcon_supbask   ,totSDgj_supbask    ,gjtable_supbask , dt,
     &  chi_supbask,mnaf_supbask,mnap_supbask,
     &  hnaf_supbask,mkdr_supbask,mka_supbask,
     &  hka_supbask,mk2_supbask,hk2_supbask,
     &  mkm_supbask,mkc_supbask,mkahp_supbask,
     &  mcat_supbask,hcat_supbask,mcal_supbask,
     &  mar_supbask)

      if (mod(O,5).eq.0) then

!     call mpi_bcast (vax_suppyrRS  ,num_suppyrRS,
!    &    mpi_double_precision, 0, mpi_comm_world, info)
!     call mpi_bcast (vax_suppyrFRB ,num_suppyrFRB,
!    &    mpi_double_precision, 1, mpi_comm_world, info)
!     call mpi_bcast (vax_tuftIB    ,num_tuftIB  ,
!    &    mpi_double_precision, 6, mpi_comm_world, info)
!     call mpi_bcast (vax_tuftRS    ,num_tuftRS   ,
!    &    mpi_double_precision, 7, mpi_comm_world, info)

       do L = firstcell, lastcell
c           k = table_axgjcompallow_suppyrRS(1)
            k = numcomp_supbask                   
            gj_axon_supbask  (L-firstcell+1) = V_supbask  (k,L)
       end do
  
           call mpi_allgather (    gj_axon_supbask ,
     &  maxcellspernode, mpi_double_precision,
     &      gj_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

      endif

      IF (mod(O,how_often).eq.0) then
! Set up distal axon voltage array and broadcast it.
c      do L = 1, num_supbask  
       do L = firstcell, lastcell
        distal_axon_supbask   (L-firstcell+1) = V_supbask   (59,L)
       end do
  
           call mpi_allgather (distal_axon_supbask,
     &  maxcellspernode, mpi_double_precision,
     &  distal_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

        field_1mm_local(1) = 0.d0     
        field_2mm_local(1) = 0.d0     
           call mpi_allgather (field_1mm_local,     
     &  1              , mpi_double_precision,
     &  field_1mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
           call mpi_allgather (field_2mm_local,     
     &  1              , mpi_double_precision,
     &  field_2mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
  
           ENDIF  ! if (mod(O,how_often).eq.0) ....

! END thisno for supbask

       ELSE IF (nodecell(thisno) .eq. 'supng    ') THEN
c supng  

c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_supng   
          lastcell = firstcell - 1 + ncellspernode_supng   

        IF (mod(O,how_often).eq.0) then
c 1st set supng   synaptic conductances to 0:

          do i = 1, numcomp_supbask
          do j = firstcell, lastcell
         gAMPA_supng  (i,j)     = 0.d0
         gNMDA_supng  (i,j)     = 0.d0
         gGABA_A_supng  (i,j)   = 0.d0
          end do
          end do

         do L = firstcell, lastcell
c Handle suppyrRS   -> supng  
      do i = 1, num_suppyrRS_to_supng    
       j = map_suppyrRS_to_supng  (i,L) ! j = presynaptic cell
       k = com_suppyrRS_to_supng  (i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_suppyrRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_suppyrRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_suppyrRS_to_supng    
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_supng  (k,L)  = gAMPA_supng  (k,L) +
     &  gAMPA_suppyrRS_to_supng   * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_supng  (k,L) = gNMDA_supng  (k,L) +
     &  gNMDA_suppyrRS_to_supng   * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_suppyrRS_to_supng    
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_supng  (k,L) = gNMDA_supng  (k,L) +
     &  gNMDA_suppyrRS_to_supng   * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_suppyrRS_to_supng    
       if (gNMDA_supng  (k,L).gt.z)
     &  gNMDA_supng  (k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle suppyrFRB  -> supng  
      do i = 1, num_suppyrFRB_to_supng    
       j = map_suppyrFRB_to_supng  (i,L) ! j = presynaptic cell
       k = com_suppyrFRB_to_supng  (i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_suppyrFRB(j)  ! enumerate presyn. spikes
        presyntime = outtime_suppyrFRB(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_suppyrFRB_to_supng    
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_supng  (k,L)  = gAMPA_supng  (k,L) +
     &  gAMPA_suppyrFRB_to_supng   * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_supng  (k,L) = gNMDA_supng  (k,L) +
     &  gNMDA_suppyrFRB_to_supng   * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_suppyrFRB_to_supng    
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_supng  (k,L) = gNMDA_supng  (k,L) +
     &  gNMDA_suppyrFRB_to_supng   * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_suppyrFRB_to_supng    
       if (gNMDA_supng  (k,L).gt.z)
     &  gNMDA_supng  (k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle supbask    -> supng  
      do i = 1, num_supbask_to_supng    
       j = map_supbask_to_supng  (i,L) ! j = presynaptic cell
       k = com_supbask_to_supng  (i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supbask(j)  ! enumerate presyn. spikes
        presyntime = outtime_supbask(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_supbask_to_supng    
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_supng  (k,L)  = gGABA_A_supng  (k,L) +
     &  gGABA_supbask_to_supng   * z      
! end GABA-A part

       end do ! m
      end do ! i

c Handle supng      -> supng   
      do i = 1, num_supng_to_supng   
       j = map_supng_to_supng   (i,L) ! j = presynaptic cell
       k = com_supng_to_supng   (i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supng(j)  ! enumerate presyn. spikes
        presyntime = outtime_supng(m,j)
        delta = time - presyntime

! GABA-A part AND GABA-B part
        dexparg = delta / tauGABA_supng_to_supng   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_supng   (k,L)  = gGABA_A_supng   (k,L) +
     &  gGABA_supng_to_supng    * z      
! end GABA-A part

       end do ! m
      end do ! i



c Handle deepTCR    -> supng  
      do i = 1, num_TCR_to_supng    
       j = map_TCR_to_supng  (i,L) ! j = presynaptic cell
       k = com_TCR_to_supng  (i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_TCR(j)  ! enumerate presyn. spikes
        presyntime = outtime_TCR(m,j)
        delta = time - presyntime - thal_cort_delay

         IF (DELTA.GE.0.d0) THEN
! AMPA part
        dexparg = delta / tauAMPA_TCR_to_supng    
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_supng  (k,L)  = gAMPA_supng  (k,L) +
     &  gAMPA_TCR_to_supng   * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_supng  (k,L) = gNMDA_supng  (k,L) +
     &  gNMDA_TCR_to_supng   * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_TCR_to_supng    
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_supng  (k,L) = gNMDA_supng  (k,L) +
     &  gNMDA_TCR_to_supng   * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_TCR_to_supng    
       if (gNMDA_supng  (k,L).gt.z)
     &  gNMDA_supng  (k,L) = z
! end NMDA part

        ENDIF  ! condition for checking that delta >= 0.
       end do ! m
      end do ! i


         end do
c End enumeration of supng    
        ENDIF  ! if (mod(O,how_often).eq.0) ....

! Define currents to supng     cells, ectopic spikes,
! tonic synaptic conductances

! Call integration routine for supng     cells
       CALL INTEGRATE_supng    (O, time, num_supng   ,
     &    V_supng   , curr_supng   ,
     $    initialize, firstcell, lastcell,
     & gAMPA_supng   , gNMDA_supng   , gGABA_A_supng   ,
     & Mg, 
     & gapcon_supng     ,totSDgj_supng      ,gjtable_supng   , dt,
     &  chi_supng  ,mnaf_supng  ,mnap_supng  ,
     &  hnaf_supng  ,mkdr_supng  ,mka_supng  ,
     &  hka_supng  ,mk2_supng  ,hk2_supng  ,
     &  mkm_supng  ,mkc_supng  ,mkahp_supng  ,
     &  mcat_supng  ,hcat_supng  ,mcal_supng  ,
     &  mar_supng  )

      if (mod(O,5).eq.0) then

       do L = firstcell, lastcell
c           k = table_axgjcompallow_suppyrRS(1)
            k = numcomp_supng                     
            gj_axon_supng    (L-firstcell+1) = V_supng    (k,L)
       end do
  
           call mpi_allgather (    gj_axon_supng   ,
     &  maxcellspernode, mpi_double_precision,
     &      gj_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

      endif

      IF (mod(O,how_often).eq.0) then
! Set up distal axon voltage array and broadcast it.
c      do L = 1, num_supbask  
       do L = firstcell, lastcell
        distal_axon_supng     (L-firstcell+1) = V_supng     (59,L)
       end do
  
           call mpi_allgather (distal_axon_supng  ,
     &  maxcellspernode, mpi_double_precision,
     &  distal_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

        field_1mm_local(1) = 0.d0     
        field_2mm_local(1) = 0.d0     
           call mpi_allgather (field_1mm_local,     
     &  1              , mpi_double_precision,
     &  field_1mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
           call mpi_allgather (field_2mm_local,     
     &  1              , mpi_double_precision,
     &  field_2mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
  
           ENDIF  ! if (mod(O,how_often).eq.0) ....

! END thisno for supng  

c      ELSE IF (THISNO.EQ.3) THEN
       ELSE IF (nodecell(thisno) .eq. 'supaxax  ') THEN
c supaxax

c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_supaxax 
          lastcell = firstcell - 1 + ncellspernode_supaxax 

         IF (mod(O,how_often).eq.0) then
c 1st set supaxax synaptic conductances to 0:

          do i = 1, numcomp_supaxax
          do j = firstcell, lastcell
         gAMPA_supaxax(i,j)     = 0.d0
         gNMDA_supaxax(i,j)     = 0.d0
         gGABA_A_supaxax(i,j)   = 0.d0
          end do
          end do

         do L = firstcell, lastcell
c Handle suppyrRS   -> supaxax
      do i = 1, num_suppyrRS_to_supaxax  
       j = map_suppyrRS_to_supaxax(i,L) ! j = presynaptic cell
       k = com_suppyrRS_to_supaxax(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_suppyrRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_suppyrRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_suppyrRS_to_supaxax  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_supaxax(k,L)  = gAMPA_supaxax(k,L) +
     &  gAMPA_suppyrRS_to_supaxax * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_supaxax(k,L) = gNMDA_supaxax(k,L) +
     &  gNMDA_suppyrRS_to_supaxax * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_suppyrRS_to_supaxax  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_supaxax(k,L) = gNMDA_supaxax(k,L) +
     &  gNMDA_suppyrRS_to_supaxax * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_suppyrRS_to_supaxax  
       if (gNMDA_supaxax(k,L).gt.z)
     &  gNMDA_supaxax(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle suppyrFRB  -> supaxax
      do i = 1, num_suppyrFRB_to_supaxax  
       j = map_suppyrFRB_to_supaxax(i,L) ! j = presynaptic cell
       k = com_suppyrFRB_to_supaxax(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_suppyrFRB(j)  ! enumerate presyn. spikes
        presyntime = outtime_suppyrFRB(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_suppyrFRB_to_supaxax  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_supaxax(k,L)  = gAMPA_supaxax(k,L) +
     &  gAMPA_suppyrFRB_to_supaxax * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_supaxax(k,L) = gNMDA_supaxax(k,L) +
     &  gNMDA_suppyrFRB_to_supaxax * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_suppyrFRB_to_supaxax  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_supaxax(k,L) = gNMDA_supaxax(k,L) +
     &  gNMDA_suppyrFRB_to_supaxax * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_suppyrFRB_to_supaxax  
       if (gNMDA_supaxax(k,L).gt.z)
     &  gNMDA_supaxax(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle supbask    -> supaxax
      do i = 1, num_supbask_to_supaxax  
       j = map_supbask_to_supaxax(i,L) ! j = presynaptic cell
       k = com_supbask_to_supaxax(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supbask(j)  ! enumerate presyn. spikes
        presyntime = outtime_supbask(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_supbask_to_supaxax  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_supaxax(k,L)  = gGABA_A_supaxax(k,L) +
     &  gGABA_supbask_to_supaxax * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle supLTS     -> supaxax
      do i = 1, num_supLTS_to_supaxax  
       j = map_supLTS_to_supaxax(i,L) ! j = presynaptic cell
       k = com_supLTS_to_supaxax(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supLTS(j)  ! enumerate presyn. spikes
        presyntime = outtime_supLTS(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_supLTS_to_supaxax  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_supaxax(k,L)  = gGABA_A_supaxax(k,L) +
     &  gGABA_supLTS_to_supaxax * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle spinstell  -> supaxax
      do i = 1, num_spinstell_to_supaxax  
       j = map_spinstell_to_supaxax(i,L) ! j = presynaptic cell
       k = com_spinstell_to_supaxax(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_spinstell(j)  ! enumerate presyn. spikes
        presyntime = outtime_spinstell(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_spinstell_to_supaxax  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_supaxax(k,L)  = gAMPA_supaxax(k,L) +
     &  gAMPA_spinstell_to_supaxax * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_supaxax(k,L) = gNMDA_supaxax(k,L) +
     &  gNMDA_spinstell_to_supaxax * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_spinstell_to_supaxax  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_supaxax(k,L) = gNMDA_supaxax(k,L) +
     &  gNMDA_spinstell_to_supaxax * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_spinstell_to_supaxax  
       if (gNMDA_supaxax(k,L).gt.z)
     &  gNMDA_supaxax(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle tuftIB     -> supaxax
      do i = 1, num_tuftIB_to_supaxax  
       j = map_tuftIB_to_supaxax(i,L) ! j = presynaptic cell
       k = com_tuftIB_to_supaxax(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_tuftIB(j)  ! enumerate presyn. spikes
        presyntime = outtime_tuftIB(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_tuftIB_to_supaxax  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_supaxax(k,L)  = gAMPA_supaxax(k,L) +
     &  gAMPA_tuftIB_to_supaxax * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_supaxax(k,L) = gNMDA_supaxax(k,L) +
     &  gNMDA_tuftIB_to_supaxax * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_tuftIB_to_supaxax  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_supaxax(k,L) = gNMDA_supaxax(k,L) +
     &  gNMDA_tuftIB_to_supaxax * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_tuftIB_to_supaxax  
       if (gNMDA_supaxax(k,L).gt.z)
     &  gNMDA_supaxax(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle tuftRS     -> supaxax
      do i = 1, num_tuftRS_to_supaxax  
       j = map_tuftRS_to_supaxax(i,L) ! j = presynaptic cell
       k = com_tuftRS_to_supaxax(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_tuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_tuftRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_tuftRS_to_supaxax  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_supaxax(k,L)  = gAMPA_supaxax(k,L) +
     &  gAMPA_tuftRS_to_supaxax * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_supaxax(k,L) = gNMDA_supaxax(k,L) +
     &  gNMDA_tuftRS_to_supaxax * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_tuftRS_to_supaxax  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_supaxax(k,L) = gNMDA_supaxax(k,L) +
     &  gNMDA_tuftRS_to_supaxax * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_tuftRS_to_supaxax  
       if (gNMDA_supaxax(k,L).gt.z)
     &  gNMDA_supaxax(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle deepLTS    -> supaxax
      do i = 1, num_deepLTS_to_supaxax  
       j = map_deepLTS_to_supaxax(i,L) ! j = presynaptic cell
       k = com_deepLTS_to_supaxax(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepLTS(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepLTS(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepLTS_to_supaxax  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_supaxax(k,L)  = gGABA_A_supaxax(k,L) +
     &  gGABA_deepLTS_to_supaxax * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle TCR        -> supaxax
      do i = 1, num_TCR_to_supaxax  
       j = map_TCR_to_supaxax(i,L) ! j = presynaptic cell
       k = com_TCR_to_supaxax(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_TCR(j)  ! enumerate presyn. spikes
        presyntime = outtime_TCR(m,j)
        delta = time - presyntime - thal_cort_delay

         IF (DELTA.GE.0.d0) THEN
! AMPA part
        dexparg = delta / tauAMPA_TCR_to_supaxax  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_supaxax(k,L)  = gAMPA_supaxax(k,L) +
     &  gAMPA_TCR_to_supaxax * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_supaxax(k,L) = gNMDA_supaxax(k,L) +
     &  gNMDA_TCR_to_supaxax * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_TCR_to_supaxax  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_supaxax(k,L) = gNMDA_supaxax(k,L) +
     &  gNMDA_TCR_to_supaxax * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_TCR_to_supaxax  
       if (gNMDA_supaxax(k,L).gt.z)
     &  gNMDA_supaxax(k,L) = z
! end NMDA part

        ENDIF  ! condition for checking that delta >= 0.
       end do ! m
      end do ! i


c Handle nontuftRS  -> supaxax
      do i = 1, num_nontuftRS_to_supaxax  
       j = map_nontuftRS_to_supaxax(i,L) ! j = presynaptic cell
       k = com_nontuftRS_to_supaxax(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_nontuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_nontuftRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_nontuftRS_to_supaxax  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_supaxax(k,L)  = gAMPA_supaxax(k,L) +
     &  gAMPA_nontuftRS_to_supaxax * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_supaxax(k,L) = gNMDA_supaxax(k,L) +
     &  gNMDA_nontuftRS_to_supaxax * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_nontuftRS_to_supaxax  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_supaxax(k,L) = gNMDA_supaxax(k,L) +
     &  gNMDA_nontuftRS_to_supaxax * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_nontuftRS_to_supaxax  
       if (gNMDA_supaxax(k,L).gt.z)
     &  gNMDA_supaxax(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


         end do
c End enumeration of supaxax  
         ENDIF  ! if (mod(O,how_often).eq.0) ...


! Define currents to supaxax   cells, ectopic spikes,
! tonic synaptic conductances

! Call integration routine for supaxax   cells
       CALL INTEGRATE_supaxaxx (O, time, num_supaxax ,
     &    V_supaxax , curr_supaxax ,
     &    initialize, firstcell, lastcell,
     & gAMPA_supaxax , gNMDA_supaxax , gGABA_A_supaxax ,
     & Mg, 
     & gapcon_supaxax   ,totSDgj_supaxax    ,gjtable_supaxax , dt,
     &  chi_supaxax,mnaf_supaxax,mnap_supaxax,
     &  hnaf_supaxax,mkdr_supaxax,mka_supaxax,
     &  hka_supaxax,mk2_supaxax,hk2_supaxax,
     &  mkm_supaxax,mkc_supaxax,mkahp_supaxax,
     &  mcat_supaxax,hcat_supaxax,mcal_supaxax,
     &  mar_supaxax)

      if (mod(O,5).eq.0) then

!     call mpi_bcast (vax_suppyrRS  ,num_suppyrRS,
!    &    mpi_double_precision, 0, mpi_comm_world, info)
!     call mpi_bcast (vax_suppyrFRB ,num_suppyrFRB,
!    &    mpi_double_precision, 1, mpi_comm_world, info)
!     call mpi_bcast (vax_tuftIB    ,num_tuftIB  ,
!    &    mpi_double_precision, 6, mpi_comm_world, info)
!     call mpi_bcast (vax_tuftRS    ,num_tuftRS   ,
!    &    mpi_double_precision, 7, mpi_comm_world, info)

       do L = firstcell, lastcell
c           k = table_axgjcompallow_suppyrRS(1)
            k = numcomp_supaxax                  
            gj_axon_supaxax  (L-firstcell+1) = V_supaxax  (k,L)
       end do
  
           call mpi_allgather (    gj_axon_supaxax ,
     &  maxcellspernode, mpi_double_precision,
     &      gj_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

      endif

        IF (mod(O,how_often).eq.0) then
! Set up distal axon voltage array and broadcast it.
c      do L = 1, num_supaxax  
       do L = firstcell, lastcell
        distal_axon_supaxax   (L-firstcell+1) = V_supaxax   (59,L)
       end do
  
           call mpi_allgather (distal_axon_supaxax, 
     &  maxcellspernode, mpi_double_precision,
     &  distal_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

        field_1mm_local(1) = 0.d0     
        field_2mm_local(1) = 0.d0     
           call mpi_allgather (field_1mm_local,     
     &  1              , mpi_double_precision,
     &  field_1mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
           call mpi_allgather (field_2mm_local,     
     &  1              , mpi_double_precision,
     &  field_2mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
  
             ENDIF !  if (mod(O,how_often).eq.0) ...

! END thisno for supaxax

c      ELSE IF (THISNO.EQ.4) THEN
       ELSE IF (nodecell(thisno) .eq. 'supLTS   ') THEN
c supLTS

c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_supLTS  
          lastcell = firstcell - 1 + ncellspernode_supLTS  

          IF (mod(O,how_often).eq.0) then
c 1st set supLTS  synaptic conductances to 0:

          do i = 1, numcomp_supLTS
          do j = firstcell, lastcell
         gAMPA_supLTS(i,j)      = 0.d0
         gNMDA_supLTS(i,j)      = 0.d0
         gGABA_A_supLTS(i,j)    = 0.d0
          end do
          end do

         do L = firstcell, lastcell
c Handle suppyrRS   -> supLTS
      do i = 1, num_suppyrRS_to_supLTS   
       j = map_suppyrRS_to_supLTS(i,L) ! j = presynaptic cell
       k = com_suppyrRS_to_supLTS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_suppyrRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_suppyrRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_suppyrRS_to_supLTS  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_supLTS(k,L)  = gAMPA_supLTS(k,L) +
     &  gAMPA_suppyrRS_to_supLTS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_supLTS(k,L) = gNMDA_supLTS(k,L) +
     &  gNMDA_suppyrRS_to_supLTS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_suppyrRS_to_supLTS  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_supLTS(k,L) = gNMDA_supLTS(k,L) +
     &  gNMDA_suppyrRS_to_supLTS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_suppyrRS_to_supLTS  
       if (gNMDA_supLTS(k,L).gt.z)
     &  gNMDA_supLTS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle suppyrFRB  -> supLTS
      do i = 1, num_suppyrFRB_to_supLTS   
       j = map_suppyrFRB_to_supLTS(i,L) ! j = presynaptic cell
       k = com_suppyrFRB_to_supLTS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_suppyrFRB(j)  ! enumerate presyn. spikes
        presyntime = outtime_suppyrFRB(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_suppyrFRB_to_supLTS  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_supLTS(k,L)  = gAMPA_supLTS(k,L) +
     &  gAMPA_suppyrFRB_to_supLTS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_supLTS(k,L) = gNMDA_supLTS(k,L) +
     &  gNMDA_suppyrFRB_to_supLTS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_suppyrFRB_to_supLTS  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_supLTS(k,L) = gNMDA_supLTS(k,L) +
     &  gNMDA_suppyrFRB_to_supLTS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_suppyrFRB_to_supLTS  
       if (gNMDA_supLTS(k,L).gt.z)
     &  gNMDA_supLTS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle supbask    -> supLTS
      do i = 1, num_supbask_to_supLTS  
       j = map_supbask_to_supLTS(i,L) ! j = presynaptic cell
       k = com_supbask_to_supLTS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supbask(j)  ! enumerate presyn. spikes
        presyntime = outtime_supbask(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_supbask_to_supLTS  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_supLTS(k,L)  = gGABA_A_supLTS(k,L) +
     &  gGABA_supbask_to_supLTS * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle supLTS     -> supLTS
      do i = 1, num_supLTS_to_supLTS  
       j = map_supLTS_to_supLTS(i,L) ! j = presynaptic cell
       k = com_supLTS_to_supLTS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supLTS(j)  ! enumerate presyn. spikes
        presyntime = outtime_supLTS(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_supLTS_to_supLTS  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_supLTS(k,L)  = gGABA_A_supLTS(k,L) +
     &  gGABA_supLTS_to_supLTS * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle spinstell  -> supLTS
      do i = 1, num_spinstell_to_supLTS  
       j = map_spinstell_to_supLTS(i,L) ! j = presynaptic cell
       k = com_spinstell_to_supLTS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_spinstell(j)  ! enumerate presyn. spikes
        presyntime = outtime_spinstell(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_spinstell_to_supLTS  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_supLTS(k,L)  = gAMPA_supLTS(k,L) +
     &  gAMPA_spinstell_to_supLTS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_supLTS(k,L) = gNMDA_supLTS(k,L) +
     &  gNMDA_spinstell_to_supLTS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_spinstell_to_supLTS  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_supLTS(k,L) = gNMDA_supLTS(k,L) +
     &  gNMDA_spinstell_to_supLTS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_spinstell_to_supLTS  
       if (gNMDA_supLTS(k,L).gt.z)
     &  gNMDA_supLTS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle tuftIB     -> supLTS
      do i = 1, num_tuftIB_to_supLTS  
       j = map_tuftIB_to_supLTS(i,L) ! j = presynaptic cell
       k = com_tuftIB_to_supLTS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_tuftIB(j)  ! enumerate presyn. spikes
        presyntime = outtime_tuftIB(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_tuftIB_to_supLTS  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_supLTS(k,L)  = gAMPA_supLTS(k,L) +
     &  gAMPA_tuftIB_to_supLTS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_supLTS(k,L) = gNMDA_supLTS(k,L) +
     &  gNMDA_tuftIB_to_supLTS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_tuftIB_to_supLTS  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_supLTS(k,L) = gNMDA_supLTS(k,L) +
     &  gNMDA_tuftIB_to_supLTS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_tuftIB_to_supLTS  
       if (gNMDA_supLTS(k,L).gt.z)
     &  gNMDA_supLTS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle tuftRS     -> supLTS
      do i = 1, num_tuftRS_to_supLTS  
       j = map_tuftRS_to_supLTS(i,L) ! j = presynaptic cell
       k = com_tuftRS_to_supLTS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_tuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_tuftRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_tuftRS_to_supLTS  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_supLTS(k,L)  = gAMPA_supLTS(k,L) +
     &  gAMPA_tuftRS_to_supLTS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_supLTS(k,L) = gNMDA_supLTS(k,L) +
     &  gNMDA_tuftRS_to_supLTS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_tuftRS_to_supLTS  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_supLTS(k,L) = gNMDA_supLTS(k,L) +
     &  gNMDA_tuftRS_to_supLTS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_tuftRS_to_supLTS  
       if (gNMDA_supLTS(k,L).gt.z)
     &  gNMDA_supLTS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle deepLTS    -> supLTS
      do i = 1, num_deepLTS_to_supLTS   
       j = map_deepLTS_to_supLTS(i,L) ! j = presynaptic cell
       k = com_deepLTS_to_supLTS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepLTS(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepLTS(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepLTS_to_supLTS   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_supLTS(k,L)  = gGABA_A_supLTS(k,L) +
     &  gGABA_deepLTS_to_supLTS * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle nontuftRS  -> supLTS
      do i = 1, num_nontuftRS_to_supLTS  
       j = map_nontuftRS_to_supLTS(i,L) ! j = presynaptic cell
       k = com_nontuftRS_to_supLTS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_nontuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_nontuftRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_nontuftRS_to_supLTS  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_supLTS(k,L)  = gAMPA_supLTS(k,L) +
     &  gAMPA_nontuftRS_to_supLTS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_supLTS(k,L) = gNMDA_supLTS(k,L) +
     &  gNMDA_nontuftRS_to_supLTS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_nontuftRS_to_supLTS  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_supLTS(k,L) = gNMDA_supLTS(k,L) +
     &  gNMDA_nontuftRS_to_supLTS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_nontuftRS_to_supLTS  
       if (gNMDA_supLTS(k,L).gt.z)
     &  gNMDA_supLTS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


         end do
c End enumeration of supLTS   
        ENDIF  ! if (mod(O,how_often).eq.0) ...

! Define currents to supLTS    cells, ectopic spikes,
! tonic synaptic conductances

! Call integration routine for supLTS    cells

       CALL INTEGRATE_supLTSx  (O, time, num_supLTS  ,
     &    V_supLTS  , curr_supLTS  ,
     &    initialize, firstcell, lastcell,
     & gAMPA_supLTS  , gNMDA_supLTS  , gGABA_A_supLTS  ,
     & Mg, 
     & gapcon_supLTS    ,totSDgj_supLTS     ,gjtable_supLTS  , dt,
     &  chi_supLTS,mnaf_supLTS,mnap_supLTS,
     &  hnaf_supLTS,mkdr_supLTS,mka_supLTS,
     &  hka_supLTS,mk2_supLTS,hk2_supLTS,
     &  mkm_supLTS,mkc_supLTS,mkahp_supLTS,
     &  mcat_supLTS,hcat_supLTS,mcal_supLTS,
     &  mar_supLTS)

      if (mod(O,5).eq.0) then

c     call mpi_bcast (vax_suppyrRS  ,num_suppyrRS,
c    &    mpi_double_precision, 0, mpi_comm_world, info)
c     call mpi_bcast (vax_suppyrFRB ,num_suppyrFRB,
c    &    mpi_double_precision, 1, mpi_comm_world, info)
c     call mpi_bcast (vax_tuftIB    ,num_tuftIB  ,
c    &    mpi_double_precision, 6, mpi_comm_world, info)
c     call mpi_bcast (vax_tuftRS    ,num_tuftRS   ,
c    &    mpi_double_precision, 7, mpi_comm_world, info)

       do L = firstcell, lastcell
c           k = table_axgjcompallow_suppyrRS(1)
            k = numcomp_supLTS                    
            gj_axon_supLTS   (L-firstcell+1) = V_supLTS   (k,L)
       end do
  
           call mpi_allgather (    gj_axon_supLTS  ,
     &  maxcellspernode, mpi_double_precision,
     &      gj_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

      endif

        IF (mod(O,how_often).eq.0) then
! Set up distal axon voltage array and broadcast it.
c      do L = 1, num_supLTS   
       do L = firstcell, lastcell
        distal_axon_supLTS    (L-firstcell+1) = V_supLTS    (59,L)
       end do
  
           call mpi_allgather (distal_axon_supLTS,   
     &  maxcellspernode, mpi_double_precision,
     &  distal_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

        field_1mm_local(1) = 0.d0     
        field_2mm_local(1) = 0.d0     
           call mpi_allgather (field_1mm_local,     
     &  1              , mpi_double_precision,
     &  field_1mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
           call mpi_allgather (field_2mm_local,     
     &  1              , mpi_double_precision,
     &  field_2mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
  
         ENDIF  ! if (mod(O,how_often).eq.0) ...

! END thisno for supLTS
 
c      ELSE IF (THISNO.EQ.5) THEN
       ELSE IF (nodecell(thisno) .eq. 'spinstell') THEN
c spinstell

c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_spinstell
          lastcell = firstcell - 1 + ncellspernode_spinstell

       IF (mod(O,how_often).eq.0) then
c 1st set spinstell synaptic conductances to 0:

          do i = 1, numcomp_spinstell
          do j = firstcell, lastcell  
         gAMPA_spinstell(i,j)   = 0.d0
         gNMDA_spinstell(i,j)   = 0.d0
         gGABA_A_spinstell(i,j) = 0.d0
         gGABA_B_spinstell(i,j) = 0.d0
          end do
          end do

         do L = firstcell, lastcell
c Handle suppyrRS    -> spinstell
      do i = 1, num_suppyrRS_to_spinstell
       j = map_suppyrRS_to_spinstell(i,L) ! j = presynaptic cell
       k = com_suppyrRS_to_spinstell(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_suppyrRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_suppyrRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_suppyrRS_to_spinstell
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_spinstell(k,L)  = gAMPA_spinstell(k,L) +
     &  gAMPA_suppyrRS_to_spinstell * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_spinstell(k,L) = gNMDA_spinstell(k,L) +
     &  gNMDA_suppyrRS_to_spinstell * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_suppyrRS_to_spinstell
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_spinstell(k,L) = gNMDA_spinstell(k,L) +
     &  gNMDA_suppyrRS_to_spinstell * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_suppyrRS_to_spinstell
       if (gNMDA_spinstell(k,L).gt.z)
     &  gNMDA_spinstell(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle suppyrFRB   -> spinstell
      do i = 1, num_suppyrFRB_to_spinstell
       j = map_suppyrFRB_to_spinstell(i,L) ! j = presynaptic cell
       k = com_suppyrFRB_to_spinstell(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_suppyrFRB(j)  ! enumerate presyn. spikes
        presyntime = outtime_suppyrFRB(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_suppyrFRB_to_spinstell
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_spinstell(k,L)  = gAMPA_spinstell(k,L) +
     &  gAMPA_suppyrFRB_to_spinstell * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_spinstell(k,L) = gNMDA_spinstell(k,L) +
     &  gNMDA_suppyrFRB_to_spinstell * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_suppyrFRB_to_spinstell
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_spinstell(k,L) = gNMDA_spinstell(k,L) +
     &  gNMDA_suppyrFRB_to_spinstell * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_suppyrFRB_to_spinstell
       if (gNMDA_spinstell(k,L).gt.z)
     &  gNMDA_spinstell(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle supbask     -> spinstell
      do i = 1, num_supbask_to_spinstell
       j = map_supbask_to_spinstell(i,L) ! j = presynaptic cell
       k = com_supbask_to_spinstell(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supbask(j)  ! enumerate presyn. spikes
        presyntime = outtime_supbask(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_supbask_to_spinstell
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_spinstell(k,L)  = gGABA_A_spinstell(k,L) +
     &  gGABA_supbask_to_spinstell * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle supaxax     -> spinstell
      do i = 1, num_supaxax_to_spinstell
       j = map_supaxax_to_spinstell(i,L) ! j = presynaptic cell
       k = com_supaxax_to_spinstell(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supaxax(j)  ! enumerate presyn. spikes
        presyntime = outtime_supaxax(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_supaxax_to_spinstell
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_spinstell(k,L)  = gGABA_A_spinstell(k,L) +
     &  gGABA_supaxax_to_spinstell * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle supLTS      -> spinstell
      do i = 1, num_supLTS_to_spinstell
       j = map_supLTS_to_spinstell(i,L) ! j = presynaptic cell
       k = com_supLTS_to_spinstell(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supLTS(j)  ! enumerate presyn. spikes
        presyntime = outtime_supLTS(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_supLTS_to_spinstell
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_spinstell(k,L)  = gGABA_A_spinstell(k,L) +
     &  gGABA_supLTS_to_spinstell * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle spinstell   -> spinstell
      do i = 1, num_spinstell_to_spinstell
       j = map_spinstell_to_spinstell(i,L) ! j = presynaptic cell
       k = com_spinstell_to_spinstell(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_spinstell(j)  ! enumerate presyn. spikes
        presyntime = outtime_spinstell(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_spinstell_to_spinstell
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_spinstell(k,L)  = gAMPA_spinstell(k,L) +
     &  gAMPA_spinstell_to_spinstell * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_spinstell(k,L) = gNMDA_spinstell(k,L) +
     &  gNMDA_spinstell_to_spinstell * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_spinstell_to_spinstell
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_spinstell(k,L) = gNMDA_spinstell(k,L) +
     &  gNMDA_spinstell_to_spinstell * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_spinstell_to_spinstell
       if (gNMDA_spinstell(k,L).gt.z)
     &  gNMDA_spinstell(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle tuftIB      -> spinstell
      do i = 1, num_tuftIB_to_spinstell
       j = map_tuftIB_to_spinstell(i,L) ! j = presynaptic cell
       k = com_tuftIB_to_spinstell(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_tuftIB(j)  ! enumerate presyn. spikes
        presyntime = outtime_tuftIB(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_tuftIB_to_spinstell
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_spinstell(k,L)  = gAMPA_spinstell(k,L) +
     &  gAMPA_tuftIB_to_spinstell * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_spinstell(k,L) = gNMDA_spinstell(k,L) +
     &  gNMDA_tuftIB_to_spinstell * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_tuftIB_to_spinstell
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_spinstell(k,L) = gNMDA_spinstell(k,L) +
     &  gNMDA_tuftIB_to_spinstell * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_tuftIB_to_spinstell
       if (gNMDA_spinstell(k,L).gt.z)
     &  gNMDA_spinstell(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle tuftRS      -> spinstell
      do i = 1, num_tuftRS_to_spinstell
       j = map_tuftRS_to_spinstell(i,L) ! j = presynaptic cell
       k = com_tuftRS_to_spinstell(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_tuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_tuftRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_tuftRS_to_spinstell
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_spinstell(k,L)  = gAMPA_spinstell(k,L) +
     &  gAMPA_tuftRS_to_spinstell * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_spinstell(k,L) = gNMDA_spinstell(k,L) +
     &  gNMDA_tuftRS_to_spinstell * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_tuftRS_to_spinstell
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_spinstell(k,L) = gNMDA_spinstell(k,L) +
     &  gNMDA_tuftRS_to_spinstell * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_tuftRS_to_spinstell
       if (gNMDA_spinstell(k,L).gt.z)
     &  gNMDA_spinstell(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle deepbask    -> spinstell
      do i = 1, num_deepbask_to_spinstell
       j = map_deepbask_to_spinstell(i,L) ! j = presynaptic cell
       k = com_deepbask_to_spinstell(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepbask(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepbask(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepbask_to_spinstell
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_spinstell(k,L)  = gGABA_A_spinstell(k,L) +
     &  gGABA_deepbask_to_spinstell * z      
! end GABA-A part

       end do ! m
      end do ! i

c Handle deepng     -> spinstell
      do i = 1, num_deepng_to_spinstell
       j = map_deepng_to_spinstell(i,L) ! j = presynaptic cell
       k = com_deepng_to_spinstell(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepng(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepng(m,j)
        delta = time - presyntime
        k0 = nint (10.d0 * delta) ! time, in units of 0.1 ms, to pass to otis_table
        if (k0 .gt. 50000) k = 50000  ! limit on size of otis_table

! GABA-A part AND GABA-B part
        dexparg = delta / tauGABA_deepng_to_spinstell
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_spinstell(k,L)  = gGABA_A_spinstell(k,L) +
     &  gGABA_deepng_to_spinstell * z      
! end GABA-A part

      gGABA_B_spinstell(k,L) = gGABA_B_spinstell(k,L) +
     &   gGABAB_deepng_to_spinstell * otis_table(k0)
! end GABA-B part

       end do ! m
      end do ! i



c Handle deepaxax    -> spinstell
      do i = 1, num_deepaxax_to_spinstell
       j = map_deepaxax_to_spinstell(i,L) ! j = presynaptic cell
       k = com_deepaxax_to_spinstell(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepaxax(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepaxax(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepaxax_to_spinstell
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_spinstell(k,L)  = gGABA_A_spinstell(k,L) +
     &  gGABA_deepaxax_to_spinstell * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle deepLTS     -> spinstell
      do i = 1, num_deepLTS_to_spinstell
       j = map_deepLTS_to_spinstell(i,L) ! j = presynaptic cell
       k = com_deepLTS_to_spinstell(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepLTS(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepLTS(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepLTS_to_spinstell
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_spinstell(k,L)  = gGABA_A_spinstell(k,L) +
     &  gGABA_deepLTS_to_spinstell * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle TCR         -> spinstell
      do i = 1, num_TCR_to_spinstell
       j = map_TCR_to_spinstell(i,L) ! j = presynaptic cell
       k = com_TCR_to_spinstell(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_TCR(j)  ! enumerate presyn. spikes
        presyntime = outtime_TCR(m,j)
        delta = time - presyntime - thal_cort_delay

         IF (DELTA.GE.0.d0) THEN
! AMPA part
        dexparg = delta / tauAMPA_TCR_to_spinstell
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_spinstell(k,L)  = gAMPA_spinstell(k,L) +
     &  gAMPA_TCR_to_spinstell * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_spinstell(k,L) = gNMDA_spinstell(k,L) +
     &  gNMDA_TCR_to_spinstell * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_TCR_to_spinstell
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_spinstell(k,L) = gNMDA_spinstell(k,L) +
     &  gNMDA_TCR_to_spinstell * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_TCR_to_spinstell 
       if (gNMDA_spinstell(k,L).gt.z)
     &  gNMDA_spinstell(k,L) = z
! end NMDA part

        ENDIF  ! condition for checking that delta >= 0.
       end do ! m
      end do ! i


c Handle nontuftRS   -> spinstell
      do i = 1, num_nontuftRS_to_spinstell
       j = map_nontuftRS_to_spinstell(i,L) ! j = presynaptic cell
       k = com_nontuftRS_to_spinstell(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_nontuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_nontuftRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_nontuftRS_to_spinstell
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_spinstell(k,L)  = gAMPA_spinstell(k,L) +
     &  gAMPA_nontuftRS_to_spinstell * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_spinstell(k,L) = gNMDA_spinstell(k,L) +
     &  gNMDA_nontuftRS_to_spinstell * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_nontuftRS_to_spinstell
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_spinstell(k,L) = gNMDA_spinstell(k,L) +
     &  gNMDA_nontuftRS_to_spinstell * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_nontuftRS_to_spinstell
       if (gNMDA_spinstell(k,L).gt.z)
     &  gNMDA_spinstell(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


         end do
c End enumeration of spinstell
       ENDIF ! if (mod(O,how_often).eq.0) ...

! Define currents to spinstell cells, ectopic spikes,
! tonic synaptic conductances

! Call integration routine for spinstell cells
       CALL INTEGRATE_spinstelldiegoxB (O, time, num_spinstell,
     &    V_spinstell, curr_spinstell,
     &    initialize, firstcell, lastcell,
     & gAMPA_spinstell, gNMDA_spinstell, gGABA_A_spinstell,
     & gGABA_B_spinstell, Mg, 
     & gapcon_spinstell,totaxgj_spinstell,gjtable_spinstell, dt,
     &  chi_spinstell,mnaf_spinstell,mnap_spinstell,
     &  hnaf_spinstell,mkdr_spinstell,mka_spinstell,
     &  hka_spinstell,mk2_spinstell,hk2_spinstell,
     &  mkm_spinstell,mkc_spinstell,mkahp_spinstell,
     &  mcat_spinstell,hcat_spinstell,mcal_spinstell,
     &  mar_spinstell)

      if (mod(O,5).eq.0) then

c     call mpi_bcast (vax_suppyrRS  ,num_suppyrRS,
c    &    mpi_double_precision, 0, mpi_comm_world, info)
c     call mpi_bcast (vax_suppyrFRB ,num_suppyrFRB,
c    &    mpi_double_precision, 1, mpi_comm_world, info)
c     call mpi_bcast (vax_tuftIB    ,num_tuftIB  ,
c    &    mpi_double_precision, 6, mpi_comm_world, info)
c     call mpi_bcast (vax_tuftRS    ,num_tuftRS   ,
c    &    mpi_double_precision, 7, mpi_comm_world, info)

       do L = firstcell, lastcell
            k = table_axgjcompallow_spinstell(1)
            gj_axon_spinstell(L-firstcell+1) = V_spinstell(k,L)
       end do
  
           call mpi_allgather (    gj_axon_spinstell,
     &  maxcellspernode, mpi_double_precision,
     &      gj_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

      endif

       IF (mod(O,how_often).eq.0) then
! Set up distal axon voltage array and broadcast it.
c      do L = 1, num_spinstell
       do L = firstcell, lastcell
        distal_axon_spinstell (L-firstcell+1) = V_spinstell (57,L)
       end do
  
           call mpi_allgather (distal_axon_spinstell,
     &  maxcellspernode, mpi_double_precision,
     &  distal_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

        field_1mm_local(1) = 0.d0     
        field_2mm_local(1) = 0.d0     
           call mpi_allgather (field_1mm_local,     
     &  1              , mpi_double_precision,
     &  field_1mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
           call mpi_allgather (field_2mm_local,     
     &  1              , mpi_double_precision,
     &  field_2mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
  
           ENDIF !  if (mod(O,how_often).eq.0) ...

! END thisno for spinstell

c      ELSE IF (THISNO.EQ.6) THEN
       ELSE IF (nodecell(thisno) .eq. 'tuftIB   ') THEN
c tuftIB

c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_tuftIB  
          lastcell = firstcell - 1 + ncellspernode_tuftIB  

         IF (mod(O,how_often).eq.0) then
c 1st set tuftIB    synaptic conductances to 0:

          do i = 1, numcomp_tuftIB
          do j = firstcell, lastcell
         gAMPA_tuftIB(i,j)      = 0.d0
         gNMDA_tuftIB(i,j)      = 0.d0
         gGABA_A_tuftIB(i,j)    = 0.d0
         gGABA_B_tuftIB(i,j)    = 0.d0
          end do
          end do

         do L = firstcell, lastcell
c Handle suppyrRS    -> tuftIB
      do i = 1, num_suppyrRS_to_tuftIB   
       j = map_suppyrRS_to_tuftIB(i,L) ! j = presynaptic cell
       k = com_suppyrRS_to_tuftIB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_suppyrRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_suppyrRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_suppyrRS_to_tuftIB   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_tuftIB(k,L)  = gAMPA_tuftIB(k,L) +
     &  gAMPA_suppyrRS_to_tuftIB * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_tuftIB(k,L) = gNMDA_tuftIB(k,L) +
     &  gNMDA_suppyrRS_to_tuftIB * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_suppyrRS_to_tuftIB   
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_tuftIB(k,L) = gNMDA_tuftIB(k,L) +
     &  gNMDA_suppyrRS_to_tuftIB * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_suppyrRS_to_tuftIB
       if (gNMDA_tuftIB(k,L).gt.z)
     &  gNMDA_tuftIB(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle suppyrFRB   -> tuftIB
      do i = 1, num_suppyrFRB_to_tuftIB   
       j = map_suppyrFRB_to_tuftIB(i,L) ! j = presynaptic cell
       k = com_suppyrFRB_to_tuftIB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_suppyrFRB(j)  ! enumerate presyn. spikes
        presyntime = outtime_suppyrFRB(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_suppyrFRB_to_tuftIB   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_tuftIB(k,L)  = gAMPA_tuftIB(k,L) +
     &  gAMPA_suppyrFRB_to_tuftIB * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_tuftIB(k,L) = gNMDA_tuftIB(k,L) +
     &  gNMDA_suppyrFRB_to_tuftIB * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_suppyrFRB_to_tuftIB   
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_tuftIB(k,L) = gNMDA_tuftIB(k,L) +
     &  gNMDA_suppyrFRB_to_tuftIB * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_suppyrFRB_to_tuftIB
       if (gNMDA_tuftIB(k,L).gt.z)
     &  gNMDA_tuftIB(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle supng      -> tuftIB
      do i = 1, num_supng_to_tuftIB
       j = map_supng_to_tuftIB(i,L) ! j = presynaptic cell
       k = com_supng_to_tuftIB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supng(j)  ! enumerate presyn. spikes
        presyntime = outtime_supng(m,j)
        delta = time - presyntime
        k0 = nint (10.d0 * delta) ! time, in units of 0.1 ms, to pass to otis_table
        if (k0 .gt. 50000) k = 50000  ! limit on size of otis_table

! GABA-A part AND GABA-B part
        dexparg = delta / tauGABA_supng_to_tuftIB
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_tuftIB(k,L)  = gGABA_A_tuftIB(k,L) +
     &  gGABA_supng_to_tuftIB * z      
! end GABA-A part

      gGABA_B_tuftIB(k,L) = gGABA_B_tuftIB(k,L) +
     &   gGABAB_supng_to_tuftIB * otis_table(k0)
! end GABA-B part

       end do ! m
      end do ! i


c Handle supaxax     -> tuftIB
      do i = 1, num_supaxax_to_tuftIB   
       j = map_supaxax_to_tuftIB(i,L) ! j = presynaptic cell
       k = com_supaxax_to_tuftIB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supaxax(j)  ! enumerate presyn. spikes
        presyntime = outtime_supaxax(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_supaxax_to_tuftIB   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_tuftIB(k,L)  = gGABA_A_tuftIB(k,L) +
     &  gGABA_supaxax_to_tuftIB * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle supLTS      -> tuftIB
      do i = 1, num_supLTS_to_tuftIB   
       j = map_supLTS_to_tuftIB(i,L) ! j = presynaptic cell
       k = com_supLTS_to_tuftIB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supLTS(j)  ! enumerate presyn. spikes
        presyntime = outtime_supLTS(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_supLTS_to_tuftIB   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_tuftIB(k,L)  = gGABA_A_tuftIB(k,L) +
     &  gGABA_supLTS_to_tuftIB * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle spinstell   -> tuftIB
      do i = 1, num_spinstell_to_tuftIB  
       j = map_spinstell_to_tuftIB(i,L) ! j = presynaptic cell
       k = com_spinstell_to_tuftIB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_spinstell(j)  ! enumerate presyn. spikes
        presyntime = outtime_spinstell(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_spinstell_to_tuftIB  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_tuftIB(k,L)  = gAMPA_tuftIB(k,L) +
     &  gAMPA_spinstell_to_tuftIB * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_tuftIB(k,L) = gNMDA_tuftIB(k,L) +
     &  gNMDA_spinstell_to_tuftIB * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_spinstell_to_tuftIB  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_tuftIB(k,L) = gNMDA_tuftIB(k,L) +
     &  gNMDA_spinstell_to_tuftIB * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_spinstell_to_tuftIB  
       if (gNMDA_tuftIB(k,L).gt.z)
     &  gNMDA_tuftIB(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle tuftIB      -> tuftIB
      do i = 1, num_tuftIB_to_tuftIB  
       j = map_tuftIB_to_tuftIB(i,L) ! j = presynaptic cell
       k = com_tuftIB_to_tuftIB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_tuftIB(j)  ! enumerate presyn. spikes
        presyntime = outtime_tuftIB(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_tuftIB_to_tuftIB  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_tuftIB(k,L)  = gAMPA_tuftIB(k,L) +
     &  gAMPA_tuftIB_to_tuftIB * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_tuftIB(k,L) = gNMDA_tuftIB(k,L) +
     &  gNMDA_tuftIB_to_tuftIB * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_tuftIB_to_tuftIB  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_tuftIB(k,L) = gNMDA_tuftIB(k,L) +
     &  gNMDA_tuftIB_to_tuftIB * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_tuftIB_to_tuftIB  
       if (gNMDA_tuftIB(k,L).gt.z)
     &  gNMDA_tuftIB(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle tuftRS      -> tuftIB
      do i = 1, num_tuftRS_to_tuftIB   
       j = map_tuftRS_to_tuftIB(i,L) ! j = presynaptic cell
       k = com_tuftRS_to_tuftIB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_tuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_tuftRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_tuftRS_to_tuftIB
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_tuftIB(k,L)  = gAMPA_tuftIB(k,L) +
     &  gAMPA_tuftRS_to_tuftIB * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_tuftIB(k,L) = gNMDA_tuftIB(k,L) +
     &  gNMDA_tuftRS_to_tuftIB * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_tuftRS_to_tuftIB
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_tuftIB(k,L) = gNMDA_tuftIB(k,L) +
     &  gNMDA_tuftRS_to_tuftIB * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_tuftRS_to_tuftIB   
       if (gNMDA_tuftIB(k,L).gt.z)
     &  gNMDA_tuftIB(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle deepbask    -> tuftIB
      do i = 1, num_deepbask_to_tuftIB   
       j = map_deepbask_to_tuftIB(i,L) ! j = presynaptic cell
       k = com_deepbask_to_tuftIB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepbask(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepbask(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepbask_to_tuftIB   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_tuftIB(k,L)  = gGABA_A_tuftIB(k,L) +
     &  gGABA_deepbask_to_tuftIB * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle deepng      -> tuftIB
      do i = 1, num_deepng_to_tuftIB
       j = map_deepng_to_tuftIB(i,L) ! j = presynaptic cell
       k = com_deepng_to_tuftIB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepng(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepng(m,j)
        delta = time - presyntime
        k0 = nint (10.d0 * delta) ! time, in units of 0.1 ms, to pass to otis_table
        if (k0 .gt. 50000) k = 50000  ! limit on size of otis_table

! GABA-A part AND GABA-B part
        dexparg = delta / tauGABA_deepng_to_tuftIB
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_tuftIB(k,L)  = gGABA_A_tuftIB(k,L) +
     &  gGABA_deepng_to_tuftIB * z      
! end GABA-A part

      gGABA_B_tuftIB(k,L) = gGABA_B_tuftIB(k,L) +
     &   gGABAB_deepng_to_tuftIB * otis_table(k0)
! end GABA-B part

       end do ! m
      end do ! i


c Handle deepaxax    -> tuftIB
      do i = 1, num_deepaxax_to_tuftIB   
       j = map_deepaxax_to_tuftIB(i,L) ! j = presynaptic cell
       k = com_deepaxax_to_tuftIB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepaxax(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepaxax(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepaxax_to_tuftIB   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_tuftIB(k,L)  = gGABA_A_tuftIB(k,L) +
     &  gGABA_deepaxax_to_tuftIB * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle deepLTS     -> tuftIB
      do i = 1, num_deepLTS_to_tuftIB   
       j = map_deepLTS_to_tuftIB(i,L) ! j = presynaptic cell
       k = com_deepLTS_to_tuftIB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepLTS(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepLTS(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepLTS_to_tuftIB   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_tuftIB(k,L)  = gGABA_A_tuftIB(k,L) +
     &  gGABA_deepLTS_to_tuftIB * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle TCR         -> tuftIB
      do i = 1, num_TCR_to_tuftIB
       j = map_TCR_to_tuftIB(i,L) ! j = presynaptic cell
       k = com_TCR_to_tuftIB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_TCR(j)  ! enumerate presyn. spikes
        presyntime = outtime_TCR(m,j)
        delta = time - presyntime - thal_cort_delay

         IF (DELTA.GE.0.d0) THEN
! AMPA part
        dexparg = delta / tauAMPA_TCR_to_tuftIB
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_tuftIB(k,L)  = gAMPA_tuftIB(k,L) +
     &  gAMPA_TCR_to_tuftIB * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_tuftIB(k,L) = gNMDA_tuftIB(k,L) +
     &  gNMDA_TCR_to_tuftIB * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_TCR_to_tuftIB
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_tuftIB(k,L) = gNMDA_tuftIB(k,L) +
     &  gNMDA_TCR_to_tuftIB * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_TCR_to_tuftIB 
       if (gNMDA_tuftIB(k,L).gt.z)
     &  gNMDA_tuftIB(k,L) = z
! end NMDA part

        ENDIF  ! condition for checking that delta >= 0.
       end do ! m
      end do ! i


c Handle nontuftRS   -> tuftIB
      do i = 1, num_nontuftRS_to_tuftIB
       j = map_nontuftRS_to_tuftIB(i,L) ! j = presynaptic cell
       k = com_nontuftRS_to_tuftIB(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_nontuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_nontuftRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_nontuftRS_to_tuftIB   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_tuftIB(k,L)  = gAMPA_tuftIB(k,L) +
     &  gAMPA_nontuftRS_to_tuftIB * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_tuftIB(k,L) = gNMDA_tuftIB(k,L) +
     &  gNMDA_nontuftRS_to_tuftIB * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_nontuftRS_to_tuftIB   
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_tuftIB(k,L) = gNMDA_tuftIB(k,L) +
     &  gNMDA_nontuftRS_to_tuftIB * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_nontuftRS_to_tuftIB   
       if (gNMDA_tuftIB(k,L).gt.z)
     &  gNMDA_tuftIB(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


         end do
c End enumeration of tuftIB   
         ENDIF  ! if (mod(O,how_often).eq.0) ....

! Define currents to tuftIB    cells, ectopic spikes,
! tonic synaptic conductances

      if (mod(O,200).eq.0) then
       call durand(seed,num_tuftIB  ,ranvec_tuftIB  ) 
        do L = firstcell, lastcell
         if ((ranvec_tuftIB  (L).gt.0.d0).and.
     &     (ranvec_tuftIB  (L).le.noisepe_tuftIB  )) then
          curr_tuftIB  (60,L) = 0.4d0
          ectr_tuftIB   = ectr_tuftIB   + 1
         else
          curr_tuftIB  (60,L) = 0.d0
         endif 
        end do
      endif

! Call integration routine for tuftIB    cells
c      CALL INTEGRATE_tuftIB (O, time, num_tuftIB,
       CALL INTEGRATE_tuftIBVx3B (O, time, num_tuftIB,
     &    V_tuftIB, curr_tuftIB,
     &  initialize, firstcell, lastcell,
     & gAMPA_tuftIB, gNMDA_tuftIB, gGABA_A_tuftIB,
     & gGABA_B_tuftIB, Mg, 
     & gapcon_tuftIB,totaxgj_tuftIB,gjtable_tuftIB, dt,
     & totaxgj_tuft  , gjtable_tuft  , num_tuftRS   ,
c    & vax_tuftRS   ,
     & v_tuftRS   ,
     &  chi_tuftIB,mnaf_tuftIB,mnap_tuftIB,
     &  hnaf_tuftIB,mkdr_tuftIB,mka_tuftIB,
     &  hka_tuftIB,mk2_tuftIB,hk2_tuftIB,
     &  mkm_tuftIB,mkc_tuftIB,mkahp_tuftIB,
     &  mcat_tuftIB,hcat_tuftIB,mcal_tuftIB,
     &  mar_tuftIB,field_1mm       ,field_2mm       ,
     &  scale_tuftIB_gKAHP, scale_tuftIB_gNaP,
     &  scale_tuftIB_gKM  , scale_tuftIB_gKA, 
     &  scale_tuftIB_gCaL, scale_tuftIB_gKC,
     & rel_axonshift_tuftIB,gCal_tuftIB,Mshift,
     & scale_tuftIB_gAR)

       IF (mod(O,5).eq.0) then
! Set up axonal gj voltage array and broadcast it to node 7
! (tuftRS cells) and receive tuftRS array - for mixed gj.
c      do L = 1, num_tuftIB  
c       vax_tuftIB (L) = V_tuftIB (61,L)
c      end do

c     call mpi_bcast (vax_suppyrRS  ,num_suppyrRS,
c    &    mpi_double_precision, 0, mpi_comm_world, info)
c     call mpi_bcast (vax_suppyrFRB ,num_suppyrFRB,
c    &    mpi_double_precision, 1, mpi_comm_world, info)
c     call mpi_bcast (vax_tuftIB    ,num_tuftIB  ,
c    &    mpi_double_precision, 6, mpi_comm_world, info)
c     call mpi_bcast (vax_tuftRS    ,num_tuftRS   ,
c    &    mpi_double_precision, 7, mpi_comm_world, info)

       do L = firstcell, lastcell
            k = table_axgjcompallow_tuftIB  (1)
            gj_axon_tuftIB   (L-firstcell+1) = V_tuftIB   (k,L)
       end do
  
           call mpi_allgather (    gj_axon_tuftIB  ,
     &  maxcellspernode, mpi_double_precision,
     &      gj_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

      ENDIF ! vax set-up, broadcasting and receiving
  

        IF (mod(O,how_often).eq.0) then
! Set up distal axon voltage array and broadcast it.
c      do L = 1, num_tuftIB   
       do L = firstcell, lastcell
        distal_axon_tuftIB    (L-firstcell+1) = V_tuftIB    (60,L)
       end do
  
           call mpi_allgather (distal_axon_tuftIB,  
     &  maxcellspernode, mpi_double_precision,
     &  distal_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

        field_1mm_local(1) = field_1mm
        field_2mm_local(1) = field_2mm
           call mpi_allgather (field_1mm_local,     
     &  1              , mpi_double_precision,
     &  field_1mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
           call mpi_allgather (field_2mm_local,     
     &  1              , mpi_double_precision,
     &  field_2mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
  
           ENDIF  ! if (mod(O,how_often).eq.0) ...

! END thisno for tuftIB

c      ELSE IF (THISNO.EQ.7) THEN
       ELSE IF (nodecell(thisno) .eq. 'tuftRS   ') THEN
c tuftRS

c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_tuftRS  
          lastcell = firstcell - 1 + ncellspernode_tuftRS  

         IF (mod(O,how_often).eq.0) then
c 1st set tuftRS    synaptic conductances to 0:

          do i = 1, numcomp_tuftRS
          do j = firstcell, lastcell
         gAMPA_tuftRS(i,j)      = 0.d0 
         gNMDA_tuftRS(i,j)      = 0.d0
         gGABA_A_tuftRS(i,j)    = 0.d0
         gGABA_B_tuftRS(i,j)    = 0.d0
          end do
          end do

         do L = firstcell, lastcell
c Handle suppyrRS    -> tuftRS
      do i = 1, num_suppyrRS_to_tuftRS   
       j = map_suppyrRS_to_tuftRS(i,L) ! j = presynaptic cell
       k = com_suppyrRS_to_tuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_suppyrRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_suppyrRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_suppyrRS_to_tuftRS   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_tuftRS(k,L)  = gAMPA_tuftRS(k,L) +
     &  gAMPA_suppyrRS_to_tuftRS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_tuftRS(k,L) = gNMDA_tuftRS(k,L) +
     &  gNMDA_suppyrRS_to_tuftRS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_suppyrRS_to_tuftRS   
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_tuftRS(k,L) = gNMDA_tuftRS(k,L) +
     &  gNMDA_suppyrRS_to_tuftRS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_suppyrRS_to_tuftRS
       if (gNMDA_tuftRS(k,L).gt.z)
     &  gNMDA_tuftRS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle suppyrFRB   -> tuftRS 
      do i = 1, num_suppyrFRB_to_tuftRS   
       j = map_suppyrFRB_to_tuftRS(i,L) ! j = presynaptic cell
       k = com_suppyrFRB_to_tuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_suppyrFRB(j)  ! enumerate presyn. spikes
        presyntime = outtime_suppyrFRB(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_suppyrFRB_to_tuftRS   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_tuftRS(k,L)  = gAMPA_tuftRS(k,L) +
     &  gAMPA_suppyrFRB_to_tuftRS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_tuftRS(k,L) = gNMDA_tuftRS(k,L) +
     &  gNMDA_suppyrFRB_to_tuftRS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_suppyrFRB_to_tuftRS   
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_tuftRS(k,L) = gNMDA_tuftRS(k,L) +
     &  gNMDA_suppyrFRB_to_tuftRS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_suppyrFRB_to_tuftRS
       if (gNMDA_tuftRS(k,L).gt.z)
     &  gNMDA_tuftRS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle supng      -> tuftRS
      do i = 1, num_supng_to_tuftRS
       j = map_supng_to_tuftRS(i,L) ! j = presynaptic cell
       k = com_supng_to_tuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supng(j)  ! enumerate presyn. spikes
        presyntime = outtime_supng(m,j)
        delta = time - presyntime
        k0 = nint (10.d0 * delta) ! time, in units of 0.1 ms, to pass to otis_table
        if (k0 .gt. 50000) k = 50000  ! limit on size of otis_table

! GABA-A part AND GABA-B part
        dexparg = delta / tauGABA_supng_to_tuftRS
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_tuftRS(k,L)  = gGABA_A_tuftRS(k,L) +
     &  gGABA_supng_to_tuftRS * z      
! end GABA-A part

      gGABA_B_tuftRS(k,L) = gGABA_B_tuftRS(k,L) +
     &   gGABAB_supng_to_tuftRS * otis_table(k0)
! end GABA-B part

       end do ! m
      end do ! i


c Handle supaxax     -> tuftRS
      do i = 1, num_supaxax_to_tuftRS   
       j = map_supaxax_to_tuftRS(i,L) ! j = presynaptic cell
       k = com_supaxax_to_tuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supaxax(j)  ! enumerate presyn. spikes
        presyntime = outtime_supaxax(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_supaxax_to_tuftRS   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_tuftRS(k,L)  = gGABA_A_tuftRS(k,L) +
     &  gGABA_supaxax_to_tuftRS * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle supLTS      -> tuftRS
      do i = 1, num_supLTS_to_tuftRS   
       j = map_supLTS_to_tuftRS(i,L) ! j = presynaptic cell
       k = com_supLTS_to_tuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supLTS(j)  ! enumerate presyn. spikes
        presyntime = outtime_supLTS(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_supLTS_to_tuftRS   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_tuftRS(k,L)  = gGABA_A_tuftRS(k,L) +
     &  gGABA_supLTS_to_tuftRS * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle spinstell   -> tuftRS
      do i = 1, num_spinstell_to_tuftRS  
       j = map_spinstell_to_tuftRS(i,L) ! j = presynaptic cell
       k = com_spinstell_to_tuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_spinstell(j)  ! enumerate presyn. spikes
        presyntime = outtime_spinstell(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_spinstell_to_tuftRS  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_tuftRS(k,L)  = gAMPA_tuftRS(k,L) +
     &  gAMPA_spinstell_to_tuftRS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_tuftRS(k,L) = gNMDA_tuftRS(k,L) +
     &  gNMDA_spinstell_to_tuftRS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_spinstell_to_tuftRS  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_tuftRS(k,L) = gNMDA_tuftRS(k,L) +
     &  gNMDA_spinstell_to_tuftRS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_spinstell_to_tuftRS  
       if (gNMDA_tuftRS(k,L).gt.z)
     &  gNMDA_tuftRS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle tuftIB      -> tuftRS
      do i = 1, num_tuftIB_to_tuftRS  
       j = map_tuftIB_to_tuftRS(i,L) ! j = presynaptic cell
       k = com_tuftIB_to_tuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_tuftIB(j)  ! enumerate presyn. spikes
        presyntime = outtime_tuftIB(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_tuftIB_to_tuftRS  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_tuftRS(k,L)  = gAMPA_tuftRS(k,L) +
     &  gAMPA_tuftIB_to_tuftRS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_tuftRS(k,L) = gNMDA_tuftRS(k,L) +
     &  gNMDA_tuftIB_to_tuftRS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_tuftIB_to_tuftRS  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_tuftRS(k,L) = gNMDA_tuftRS(k,L) +
     &  gNMDA_tuftIB_to_tuftRS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_tuftIB_to_tuftRS  
       if (gNMDA_tuftRS(k,L).gt.z)
     &  gNMDA_tuftRS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle tuftRS      -> tuftRS
      do i = 1, num_tuftRS_to_tuftRS  
       j = map_tuftRS_to_tuftRS(i,L) ! j = presynaptic cell
       k = com_tuftRS_to_tuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_tuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_tuftRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_tuftRS_to_tuftRS  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_tuftRS(k,L)  = gAMPA_tuftRS(k,L) +
     &  gAMPA_tuftRS_to_tuftRS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_tuftRS(k,L) = gNMDA_tuftRS(k,L) +
     &  gNMDA_tuftRS_to_tuftRS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_tuftRS_to_tuftRS  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_tuftRS(k,L) = gNMDA_tuftRS(k,L) +
     &  gNMDA_tuftRS_to_tuftRS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_tuftRS_to_tuftRS  
       if (gNMDA_tuftRS(k,L).gt.z)
     &  gNMDA_tuftRS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle deepbask    -> tuftRS
      do i = 1, num_deepbask_to_tuftRS   
       j = map_deepbask_to_tuftRS(i,L) ! j = presynaptic cell
       k = com_deepbask_to_tuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepbask(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepbask(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepbask_to_tuftRS   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_tuftRS(k,L)  = gGABA_A_tuftRS(k,L) +
     &  gGABA_deepbask_to_tuftRS * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle deepng      -> tuftRS
      do i = 1, num_deepng_to_tuftRS
       j = map_deepng_to_tuftRS(i,L) ! j = presynaptic cell
       k = com_deepng_to_tuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepng(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepng(m,j)
        delta = time - presyntime
        k0 = nint (10.d0 * delta) ! time, in units of 0.1 ms, to pass to otis_table
        if (k0 .gt. 50000) k = 50000  ! limit on size of otis_table

! GABA-A part AND GABA-B part
        dexparg = delta / tauGABA_deepng_to_tuftRS
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_tuftRS(k,L)  = gGABA_A_tuftRS(k,L) +
     &  gGABA_deepng_to_tuftRS * z      
! end GABA-A part

      gGABA_B_tuftRS(k,L) = gGABA_B_tuftRS(k,L) +
     &   gGABAB_deepng_to_tuftRS * otis_table(k0)
! end GABA-B part

       end do ! m
      end do ! i


c Handle deepaxax    -> tuftRS
      do i = 1, num_deepaxax_to_tuftRS   
       j = map_deepaxax_to_tuftRS(i,L) ! j = presynaptic cell
       k = com_deepaxax_to_tuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepaxax(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepaxax(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepaxax_to_tuftRS   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_tuftRS(k,L)  = gGABA_A_tuftRS(k,L) +
     &  gGABA_deepaxax_to_tuftRS * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle deepLTS     -> tuftRS
      do i = 1, num_deepLTS_to_tuftRS   
       j = map_deepLTS_to_tuftRS(i,L) ! j = presynaptic cell
       k = com_deepLTS_to_tuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepLTS(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepaxax(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepLTS_to_tuftRS   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_tuftRS(k,L)  = gGABA_A_tuftRS(k,L) +
     &  gGABA_deepLTS_to_tuftRS * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle TCR         -> tuftRS
      do i = 1, num_TCR_to_tuftRS
       j = map_TCR_to_tuftRS(i,L) ! j = presynaptic cell
       k = com_TCR_to_tuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_TCR(j)  ! enumerate presyn. spikes
        presyntime = outtime_TCR(m,j)
        delta = time - presyntime - thal_cort_delay

         IF (DELTA.GE.0.d0) THEN
! AMPA part
        dexparg = delta / tauAMPA_TCR_to_tuftRS
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_tuftRS(k,L)  = gAMPA_tuftRS(k,L) +
     &  gAMPA_TCR_to_tuftRS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_tuftRS(k,L) = gNMDA_tuftRS(k,L) +
     &  gNMDA_TCR_to_tuftRS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_TCR_to_tuftRS
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_tuftRS(k,L) = gNMDA_tuftRS(k,L) +
     &  gNMDA_TCR_to_tuftRS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_TCR_to_tuftRS 
       if (gNMDA_tuftRS(k,L).gt.z)
     &  gNMDA_tuftRS(k,L) = z
! end NMDA part

        ENDIF  ! condition for checking that delta >= 0.
       end do ! m
      end do ! i


c Handle nontuftRS   -> tuftRS
      do i = 1, num_nontuftRS_to_tuftRS  
       j = map_nontuftRS_to_tuftRS(i,L) ! j = presynaptic cell
       k = com_nontuftRS_to_tuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_nontuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_nontuftRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_nontuftRS_to_tuftRS  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_tuftRS(k,L)  = gAMPA_tuftRS(k,L) +
     &  gAMPA_nontuftRS_to_tuftRS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_tuftRS(k,L) = gNMDA_tuftRS(k,L) +
     &  gNMDA_nontuftRS_to_tuftRS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_nontuftRS_to_tuftRS  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_tuftRS(k,L) = gNMDA_tuftRS(k,L) +
     &  gNMDA_nontuftRS_to_tuftRS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_nontuftRS_to_tuftRS  
       if (gNMDA_tuftRS(k,L).gt.z)
     &  gNMDA_tuftRS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


         end do
c End enumeration of tuftRS   
        ENDIF  ! if (mod(O,how_often).eq.0) ...

! Define currents to tuftRS    cells, ectopic spikes,
! tonic synaptic conductances

      if (mod(O,200).eq.0) then
       call durand(seed,num_tuftRS  ,ranvec_tuftRS  ) 
        do L = firstcell, lastcell
         if ((ranvec_tuftRS  (L).gt.0.d0).and.
     &     (ranvec_tuftRS  (L).le.noisepe_tuftRS  )) then
          curr_tuftRS  (60,L) = 0.4d0
          ectr_tuftRS   = ectr_tuftRS   + 1
         else
          curr_tuftRS  (60,L) = 0.d0
         endif 
        end do
      endif

! Call integration routine for tuftRS    cells
       CALL INTEGRATE_tuftRSXXB (O, time, num_tuftRS,
     &    V_tuftRS, curr_tuftRS,
     & initialize, firstcell, lastcell,
     & gAMPA_tuftRS, gNMDA_tuftRS, gGABA_A_tuftRS,
     & gGABA_B_tuftRS, Mg, 
     & gapcon_tuftRS,totaxgj_tuftRS,gjtable_tuftRS, dt,
     & totaxgj_tuft  , gjtable_tuft  , num_tuftIB   ,
c    & vax_tuftIB   ,
     & v_tuftIB   ,
     &  chi_tuftRS,mnaf_tuftRS,mnap_tuftRS,
     &  hnaf_tuftRS,mkdr_tuftRS,mka_tuftRS,
     &  hka_tuftRS,mk2_tuftRS,hk2_tuftRS,
     &  mkm_tuftRS,mkc_tuftRS,mkahp_tuftRS,
     &  mcat_tuftRS,hcat_tuftRS,mcal_tuftRS,
     &  mar_tuftRS,field_1mm       ,field_2mm       )

       IF (mod(O,5).eq.0) then
! Set up axonal gj voltage array and broadcast it to node 6
! (tuftIB cells) and receive tuftIB array - for mixed gj.
c      do L = 1, num_tuftRS  
c       vax_tuftRS (L) = V_tuftRS (61,L)
c      end do

c     call mpi_bcast (vax_suppyrRS  ,num_suppyrRS,
c    &    mpi_double_precision, 0, mpi_comm_world, info)
c     call mpi_bcast (vax_suppyrFRB ,num_suppyrFRB,
c    &    mpi_double_precision, 1, mpi_comm_world, info)
c     call mpi_bcast (vax_tuftIB    ,num_tuftIB  ,
c    &    mpi_double_precision, 6, mpi_comm_world, info)
c     call mpi_bcast (vax_tuftRS    ,num_tuftRS   ,
c    &    mpi_double_precision, 7, mpi_comm_world, info)

       do L = firstcell, lastcell
            k = table_axgjcompallow_tuftRS  (1)
            gj_axon_tuftRS   (L-firstcell+1) = V_tuftRS   (k,L)
       end do
  
           call mpi_allgather (    gj_axon_tuftRS  ,
     &  maxcellspernode, mpi_double_precision,
     &      gj_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

      ENDIF ! vax set-up, broadcasting and receiving
  

       IF (mod(O,how_often).eq.0) then
! Set up distal axon voltage array and broadcast it.
c      do L = 1, num_tuftRS   
       do L = firstcell, lastcell
        distal_axon_tuftRS    (L-firstcell+1) = V_tuftRS    (60,L)
       end do
  
           call mpi_allgather (distal_axon_tuftRS,  
     &  maxcellspernode, mpi_double_precision,
     &  distal_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

        field_1mm_local(1) = field_1mm
        field_2mm_local(1) = field_2mm
           call mpi_allgather (field_1mm_local,     
     &  1              , mpi_double_precision,
     &  field_1mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
           call mpi_allgather (field_2mm_local,     
     &  1              , mpi_double_precision,
     &  field_2mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
  
         ENDIF  !  if (mod(O,how_often).eq.0) ...

! END thisno for tuftRS

c      ELSE IF (THISNO.EQ.8) THEN
       ELSE IF (nodecell(thisno) .eq. 'nontuftRS') THEN
c nontuftRS

c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_nontuftRS
          lastcell = firstcell - 1 + ncellspernode_nontuftRS

         IF (mod(O,how_often).eq.0) then
c 1st set nontuftRS synaptic conductances to 0:

          do i = 1, numcomp_nontuftRS
          do j = firstcell, lastcell
         gAMPA_nontuftRS(i,j)   = 0.d0 
         gNMDA_nontuftRS(i,j)   = 0.d0 
         gGABA_A_nontuftRS(i,j) = 0.d0
         gGABA_B_nontuftRS(i,j) = 0.d0
          end do
          end do

         do L = firstcell, lastcell
c Handle suppyrRS   -> nontuftRS
      do i = 1, num_suppyrRS_to_nontuftRS   
       j = map_suppyrRS_to_nontuftRS(i,L) ! j = presynaptic cell
       k = com_suppyrRS_to_nontuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_suppyrRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_suppyrRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_suppyrRS_to_nontuftRS   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_nontuftRS(k,L)  = gAMPA_nontuftRS(k,L) +
     &  gAMPA_suppyrRS_to_nontuftRS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_nontuftRS(k,L) = gNMDA_nontuftRS(k,L) +
     &  gNMDA_suppyrRS_to_nontuftRS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_suppyrRS_to_nontuftRS   
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_nontuftRS(k,L) = gNMDA_nontuftRS(k,L) +
     &  gNMDA_suppyrRS_to_nontuftRS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_suppyrRS_to_nontuftRS
       if (gNMDA_nontuftRS(k,L).gt.z)
     &  gNMDA_nontuftRS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle suppyrFRB  -> nontuftRS
      do i = 1, num_suppyrFRB_to_nontuftRS   
       j = map_suppyrFRB_to_nontuftRS(i,L) ! j = presynaptic cell
       k = com_suppyrFRB_to_nontuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_suppyrFRB(j)  ! enumerate presyn. spikes
        presyntime = outtime_suppyrFRB(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_suppyrFRB_to_nontuftRS   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_nontuftRS(k,L)  = gAMPA_nontuftRS(k,L) +
     &  gAMPA_suppyrFRB_to_nontuftRS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_nontuftRS(k,L) = gNMDA_nontuftRS(k,L) +
     &  gNMDA_suppyrFRB_to_nontuftRS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_suppyrFRB_to_nontuftRS   
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_nontuftRS(k,L) = gNMDA_nontuftRS(k,L) +
     &  gNMDA_suppyrFRB_to_nontuftRS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_suppyrFRB_to_nontuftRS
       if (gNMDA_nontuftRS(k,L).gt.z)
     &  gNMDA_nontuftRS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle supng      -> nontuftRS
      do i = 1, num_supng_to_nontuftRS
       j = map_supng_to_nontuftRS(i,L) ! j = presynaptic cell
       k = com_supng_to_nontuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supng(j)  ! enumerate presyn. spikes
        presyntime = outtime_supng(m,j)
        delta = time - presyntime
        k0 = nint (10.d0 * delta) ! time, in units of 0.1 ms, to pass to otis_table
        if (k0 .gt. 50000) k = 50000  ! limit on size of otis_table

! GABA-A part AND GABA-B part
        dexparg = delta / tauGABA_supng_to_nontuftRS
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_nontuftRS(k,L)  = gGABA_A_nontuftRS(k,L) +
     &  gGABA_supng_to_nontuftRS * z      
! end GABA-A part

      gGABA_B_nontuftRS(k,L) = gGABA_B_nontuftRS(k,L) +
     &   gGABAB_supng_to_nontuftRS * otis_table(k0)
! end GABA-B part

       end do ! m
      end do ! i


c Handle supaxax    -> nontuftRS
      do i = 1, num_supaxax_to_nontuftRS   
       j = map_supaxax_to_nontuftRS(i,L) ! j = presynaptic cell
       k = com_supaxax_to_nontuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supaxax(j)  ! enumerate presyn. spikes
        presyntime = outtime_supaxax(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_supaxax_to_nontuftRS   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_nontuftRS(k,L)  = gGABA_A_nontuftRS(k,L) +
     &  gGABA_supaxax_to_nontuftRS * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle supLTS     -> nontuftRS
      do i = 1, num_supLTS_to_nontuftRS   
       j = map_supLTS_to_nontuftRS(i,L) ! j = presynaptic cell
       k = com_supLTS_to_nontuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supLTS(j)  ! enumerate presyn. spikes
        presyntime = outtime_supLTS(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_supLTS_to_nontuftRS   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_nontuftRS(k,L)  = gGABA_A_nontuftRS(k,L) +
     &  gGABA_supLTS_to_nontuftRS * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle spinstell  -> nontuftRS
      do i = 1, num_spinstell_to_nontuftRS  
       j = map_spinstell_to_nontuftRS(i,L) ! j = presynaptic cell
       k = com_spinstell_to_nontuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_spinstell(j)  ! enumerate presyn. spikes
        presyntime = outtime_spinstell(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_spinstell_to_nontuftRS  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_nontuftRS(k,L)  = gAMPA_nontuftRS(k,L) +
     &  gAMPA_spinstell_to_nontuftRS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_nontuftRS(k,L) = gNMDA_nontuftRS(k,L) +
     &  gNMDA_spinstell_to_nontuftRS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_spinstell_to_nontuftRS  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_nontuftRS(k,L) = gNMDA_nontuftRS(k,L) +
     &  gNMDA_spinstell_to_nontuftRS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_spinstell_to_nontuftRS  
       if (gNMDA_nontuftRS(k,L).gt.z)
     &  gNMDA_nontuftRS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle tuftIB     -> nontuftRS
      do i = 1, num_tuftIB_to_nontuftRS  
       j = map_tuftIB_to_nontuftRS(i,L) ! j = presynaptic cell
       k = com_tuftIB_to_nontuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_tuftIB(j)  ! enumerate presyn. spikes
        presyntime = outtime_tuftIB(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_tuftIB_to_nontuftRS  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_nontuftRS(k,L)  = gAMPA_nontuftRS(k,L) +
     &  gAMPA_tuftIB_to_nontuftRS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_nontuftRS(k,L) = gNMDA_nontuftRS(k,L) +
     &  gNMDA_tuftIB_to_nontuftRS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_tuftIB_to_nontuftRS  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_nontuftRS(k,L) = gNMDA_nontuftRS(k,L) +
     &  gNMDA_tuftIB_to_nontuftRS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_tuftIB_to_nontuftRS  
       if (gNMDA_nontuftRS(k,L).gt.z)
     &  gNMDA_nontuftRS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle tuftRS     -> nontuftRS
      do i = 1, num_tuftRS_to_nontuftRS  
       j = map_tuftRS_to_nontuftRS(i,L) ! j = presynaptic cell
       k = com_tuftRS_to_nontuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_tuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_tuftRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_tuftRS_to_nontuftRS  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_nontuftRS(k,L)  = gAMPA_nontuftRS(k,L) +
     &  gAMPA_tuftRS_to_nontuftRS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_nontuftRS(k,L) = gNMDA_nontuftRS(k,L) +
     &  gNMDA_tuftRS_to_nontuftRS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_tuftRS_to_nontuftRS  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_nontuftRS(k,L) = gNMDA_nontuftRS(k,L) +
     &  gNMDA_tuftRS_to_nontuftRS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_tuftRS_to_nontuftRS  
       if (gNMDA_nontuftRS(k,L).gt.z)
     &  gNMDA_nontuftRS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle deepbask   -> nontuftRS
      do i = 1, num_deepbask_to_nontuftRS   
       j = map_deepbask_to_nontuftRS(i,L) ! j = presynaptic cell
       k = com_deepbask_to_nontuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepbask(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepbask(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepbask_to_nontuftRS   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_nontuftRS(k,L)  = gGABA_A_nontuftRS(k,L) +
     &  gGABA_deepbask_to_nontuftRS * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle deepng      -> nontuftRS
      do i = 1, num_deepng_to_nontuftRS
       j = map_deepng_to_nontuftRS(i,L) ! j = presynaptic cell
       k = com_deepng_to_nontuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepng(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepng(m,j)
        delta = time - presyntime
        k0 = nint (10.d0 * delta) ! time, in units of 0.1 ms, to pass to otis_table
        if (k0 .gt. 50000) k = 50000  ! limit on size of otis_table

! GABA-A part AND GABA-B part
        dexparg = delta / tauGABA_deepng_to_nontuftRS
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_nontuftRS(k,L)  = gGABA_A_nontuftRS(k,L) +
     &  gGABA_deepng_to_nontuftRS * z      
! end GABA-A part

      gGABA_B_nontuftRS(k,L) = gGABA_B_nontuftRS(k,L) +
     &   gGABAB_deepng_to_nontuftRS * otis_table(k0)
! end GABA-B part

       end do ! m
      end do ! i


c Handle deepaxax   -> nontuftRS
      do i = 1, num_deepaxax_to_nontuftRS   
       j = map_deepaxax_to_nontuftRS(i,L) ! j = presynaptic cell
       k = com_deepaxax_to_nontuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepaxax(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepaxax(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepaxax_to_nontuftRS   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_nontuftRS(k,L)  = gGABA_A_nontuftRS(k,L) +
     &  gGABA_deepaxax_to_nontuftRS * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle deepLTS    -> nontuftRS
      do i = 1, num_deepLTS_to_nontuftRS   
       j = map_deepLTS_to_nontuftRS(i,L) ! j = presynaptic cell
       k = com_deepLTS_to_nontuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepLTS(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepLTS(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepLTS_to_nontuftRS   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_nontuftRS(k,L)  = gGABA_A_nontuftRS(k,L) +
     &  gGABA_deepLTS_to_nontuftRS * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle TCR        -> nontuftRS
      do i = 1, num_TCR_to_nontuftRS
       j = map_TCR_to_nontuftRS(i,L) ! j = presynaptic cell
       k = com_TCR_to_nontuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_TCR(j)  ! enumerate presyn. spikes
        presyntime = outtime_TCR(m,j)
        delta = time - presyntime - thal_cort_delay

         IF (DELTA.GE.0.d0) THEN
! AMPA part
        dexparg = delta / tauAMPA_TCR_to_nontuftRS
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_nontuftRS(k,L)  = gAMPA_nontuftRS(k,L) +
     &  gAMPA_TCR_to_nontuftRS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_nontuftRS(k,L) = gNMDA_nontuftRS(k,L) +
     &  gNMDA_TCR_to_nontuftRS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_TCR_to_nontuftRS
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_nontuftRS(k,L) = gNMDA_nontuftRS(k,L) +
     &  gNMDA_TCR_to_nontuftRS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_TCR_to_nontuftRS 
       if (gNMDA_nontuftRS(k,L).gt.z)
     &  gNMDA_nontuftRS(k,L) = z
! end NMDA part

        ENDIF  ! condition for checking that delta >= 0.
       end do ! m
      end do ! i


c Handle nontuftRS  -> nontuftRS
      do i = 1, num_nontuftRS_to_nontuftRS  
       j = map_nontuftRS_to_nontuftRS(i,L) ! j = presynaptic cell
       k = com_nontuftRS_to_nontuftRS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_nontuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_nontuftRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_nontuftRS_to_nontuftRS  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_nontuftRS(k,L)  = gAMPA_nontuftRS(k,L) +
     &  gAMPA_nontuftRS_to_nontuftRS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_nontuftRS(k,L) = gNMDA_nontuftRS(k,L) +
     &  gNMDA_nontuftRS_to_nontuftRS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_nontuftRS_to_nontuftRS  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_nontuftRS(k,L) = gNMDA_nontuftRS(k,L) +
     &  gNMDA_nontuftRS_to_nontuftRS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_nontuftRS_to_nontuftRS  
       if (gNMDA_nontuftRS(k,L).gt.z)
     &  gNMDA_nontuftRS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


         end do
c End enumeration of nontuftRS   
          ENDIF  ! if (mod(O,how_often).eq.0) ...

! Define currents to nontuftRS    cells, ectopic spikes,
! tonic synaptic conductances

      if (mod(O,200).eq.0) then
       call durand(seed,num_nontuftRS  ,ranvec_nontuftRS  ) 
        do L = firstcell, lastcell
         if ((ranvec_nontuftRS  (L).gt.0.d0).and.
     &     (ranvec_nontuftRS  (L).le.noisepe_nontuftRS  )) then
          curr_nontuftRS  (48,L) = 0.4d0
          ectr_nontuftRS   = ectr_nontuftRS   + 1
         else
          curr_nontuftRS  (48,L) = 0.d0
         endif 
        end do
      endif

! Call integration routine for nontuftRS    cells
       CALL INTEGRATE_nontuftRSXXB (O, time, num_nontuftRS,
     &    V_nontuftRS, curr_nontuftRS,
     &  initialize, firstcell, lastcell,
     & gAMPA_nontuftRS, gNMDA_nontuftRS, gGABA_A_nontuftRS,
     & gGABA_B_nontuftRS, Mg, 
     & gapcon_nontuftRS,totaxgj_nontuftRS,gjtable_nontuftRS, dt,
     &  chi_nontuftRS,mnaf_nontuftRS,mnap_nontuftRS,
     &  hnaf_nontuftRS,mkdr_nontuftRS,mka_nontuftRS,
     &  hka_nontuftRS,mk2_nontuftRS,hk2_nontuftRS,
     &  mkm_nontuftRS,mkc_nontuftRS,mkahp_nontuftRS,
     &  mcat_nontuftRS,hcat_nontuftRS,mcal_nontuftRS,
     &  mar_nontuftRS,field_1mm          ,field_2mm          ,
     &  nontuftRS_nFRB)

      if (mod(O,5).eq.0) then

c     call mpi_bcast (vax_suppyrRS  ,num_suppyrRS,
c    &    mpi_double_precision, 0, mpi_comm_world, info)
c     call mpi_bcast (vax_suppyrFRB ,num_suppyrFRB,
c    &    mpi_double_precision, 1, mpi_comm_world, info)
c     call mpi_bcast (vax_tuftIB    ,num_tuftIB  ,
c    &    mpi_double_precision, 6, mpi_comm_world, info)
c     call mpi_bcast (vax_tuftRS    ,num_tuftRS   ,
c    &    mpi_double_precision, 7, mpi_comm_world, info)

       do L = firstcell, lastcell
            k = table_axgjcompallow_nontuftRS(1)
            gj_axon_nontuftRS(L-firstcell+1) = V_nontuftRS(k,L)
       end do
  
           call mpi_allgather (    gj_axon_nontuftRS,
     &  maxcellspernode, mpi_double_precision,
     &      gj_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

      endif

        IF (mod(O,how_often).eq.0) then
! Set up distal axon voltage array and broadcast it.
c      do L = 1, num_nontuftRS   
       do L = firstcell, lastcell
        distal_axon_nontuftRS    (L-firstcell+1) = V_nontuftRS    (48,L)
       end do
  
           call mpi_allgather (distal_axon_nontuftRS,
     &  maxcellspernode, mpi_double_precision,
     &  distal_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

        field_1mm_local(1) = field_1mm
        field_2mm_local(1) = field_2mm
           call mpi_allgather (field_1mm_local,     
     &  1              , mpi_double_precision,
     &  field_1mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
           call mpi_allgather (field_2mm_local,     
     &  1              , mpi_double_precision,
     &  field_2mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
  
         ENDIF  !  if (mod(O,how_often).eq.0) ...

! END thisno for nontuftRS

c      ELSE IF (THISNO.EQ.9) THEN
       ELSE IF (nodecell(thisno) .eq. 'deepbask ') THEN
c deepbask

c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_deepbask
          lastcell = firstcell - 1 + ncellspernode_deepbask

          IF (mod(O,how_often).eq.0) then
c 1st set deepbask  synaptic conductances to 0:

          do i = 1, numcomp_deepbask
          do j = firstcell, lastcell
         gAMPA_deepbask(i,j)    = 0.d0
         gNMDA_deepbask(i,j)    = 0.d0
         gGABA_A_deepbask(i,j)  = 0.d0
          end do
          end do

         do L = firstcell, lastcell
c Handle suppyrRS   -> deepbask
      do i = 1, num_suppyrRS_to_deepbask  
       j = map_suppyrRS_to_deepbask(i,L) ! j = presynaptic cell
       k = com_suppyrRS_to_deepbask(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_suppyrRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_suppyrRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_suppyrRS_to_deepbask  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_deepbask(k,L)  = gAMPA_deepbask(k,L) +
     &  gAMPA_suppyrRS_to_deepbask * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_deepbask(k,L) = gNMDA_deepbask(k,L) +
     &  gNMDA_suppyrRS_to_deepbask * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_suppyrRS_to_deepbask  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_deepbask(k,L) = gNMDA_deepbask(k,L) +
     &  gNMDA_suppyrRS_to_deepbask * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_suppyrRS_to_deepbask  
       if (gNMDA_deepbask(k,L).gt.z)
     &  gNMDA_deepbask(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle suppyrFRB  -> deepbask
      do i = 1, num_suppyrFRB_to_deepbask  
       j = map_suppyrFRB_to_deepbask(i,L) ! j = presynaptic cell
       k = com_suppyrFRB_to_deepbask(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_suppyrFRB(j)  ! enumerate presyn. spikes
        presyntime = outtime_suppyrFRB(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_suppyrFRB_to_deepbask  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_deepbask(k,L)  = gAMPA_deepbask(k,L) +
     &  gAMPA_suppyrFRB_to_deepbask * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_deepbask(k,L) = gNMDA_deepbask(k,L) +
     &  gNMDA_suppyrFRB_to_deepbask * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_suppyrFRB_to_deepbask  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_deepbask(k,L) = gNMDA_deepbask(k,L) +
     &  gNMDA_suppyrFRB_to_deepbask * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_suppyrFRB_to_deepbask  
       if (gNMDA_deepbask(k,L).gt.z)
     &  gNMDA_deepbask(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle supLTS     -> deepbask
      do i = 1, num_supLTS_to_deepbask    
       j = map_supLTS_to_deepbask(i,L) ! j = presynaptic cell
       k = com_supLTS_to_deepbask(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supLTS(j)  ! enumerate presyn. spikes
        presyntime = outtime_supLTS(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_supLTS_to_deepbask    
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_deepbask(k,L)  = gGABA_A_deepbask(k,L) +
     &  gGABA_supLTS_to_deepbask * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle spinstell  -> deepbask
      do i = 1, num_spinstell_to_deepbask   
       j = map_spinstell_to_deepbask(i,L) ! j = presynaptic cell
       k = com_spinstell_to_deepbask(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_spinstell(j)  ! enumerate presyn. spikes
        presyntime = outtime_spinstell(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_spinstell_to_deepbask  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_deepbask(k,L)  = gAMPA_deepbask(k,L) +
     &  gAMPA_spinstell_to_deepbask * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_deepbask(k,L) = gNMDA_deepbask(k,L) +
     &  gNMDA_spinstell_to_deepbask * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_spinstell_to_deepbask  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_deepbask(k,L) = gNMDA_deepbask(k,L) +
     &  gNMDA_spinstell_to_deepbask * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_spinstell_to_deepbask  
       if (gNMDA_deepbask(k,L).gt.z)
     &  gNMDA_deepbask(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle tuftIB     -> deepbask
      do i = 1, num_tuftIB_to_deepbask   
       j = map_tuftIB_to_deepbask(i,L) ! j = presynaptic cell
       k = com_tuftIB_to_deepbask(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_tuftIB(j)  ! enumerate presyn. spikes
        presyntime = outtime_tuftIB(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_tuftIB_to_deepbask  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_deepbask(k,L)  = gAMPA_deepbask(k,L) +
     &  gAMPA_tuftIB_to_deepbask * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_deepbask(k,L) = gNMDA_deepbask(k,L) +
     &  gNMDA_tuftIB_to_deepbask * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_tuftIB_to_deepbask  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_deepbask(k,L) = gNMDA_deepbask(k,L) +
     &  gNMDA_tuftIB_to_deepbask * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_tuftIB_to_deepbask  
       if (gNMDA_deepbask(k,L).gt.z)
     &  gNMDA_deepbask(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle tuftRS     -> deepbask
      do i = 1, num_tuftRS_to_deepbask   
       j = map_tuftRS_to_deepbask(i,L) ! j = presynaptic cell
       k = com_tuftRS_to_deepbask(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_tuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_tuftRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_tuftRS_to_deepbask  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_deepbask(k,L)  = gAMPA_deepbask(k,L) +
     &  gAMPA_tuftRS_to_deepbask * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_deepbask(k,L) = gNMDA_deepbask(k,L) +
     &  gNMDA_tuftRS_to_deepbask * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_tuftRS_to_deepbask  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_deepbask(k,L) = gNMDA_deepbask(k,L) +
     &  gNMDA_tuftRS_to_deepbask * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_tuftRS_to_deepbask  
       if (gNMDA_deepbask(k,L).gt.z)
     &  gNMDA_deepbask(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle deepbask   -> deepbask
      do i = 1, num_deepbask_to_deepbask    
       j = map_deepbask_to_deepbask(i,L) ! j = presynaptic cell
       k = com_deepbask_to_deepbask(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepbask(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepbask(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepbask_to_deepbask    
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_deepbask(k,L)  = gGABA_A_deepbask(k,L) +
     &  gGABA_deepbask_to_deepbask * z      
! end GABA-A part

       end do ! m
      end do ! i

c Handle deepng     -> deepbask
      do i = 1, num_deepng_to_deepbask    
       j = map_deepng_to_deepbask(i,L) ! j = presynaptic cell
       k = com_deepng_to_deepbask(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepng(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepng(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepng_to_deepbask    
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_deepbask(k,L)  = gGABA_A_deepbask(k,L) +
     &  gGABA_deepng_to_deepbask * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle deepLTS    -> deepbask
      do i = 1, num_deepLTS_to_deepbask    
       j = map_deepLTS_to_deepbask(i,L) ! j = presynaptic cell
       k = com_deepLTS_to_deepbask(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepLTS(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepLTS(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepLTS_to_deepbask    
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_deepbask(k,L)  = gGABA_A_deepbask(k,L) +
     &  gGABA_deepLTS_to_deepbask * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle TCR        -> deepbask
      do i = 1, num_TCR_to_deepbask 
       j = map_TCR_to_deepbask(i,L) ! j = presynaptic cell
       k = com_TCR_to_deepbask(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_TCR(j)  ! enumerate presyn. spikes
        presyntime = outtime_TCR(m,j)
        delta = time - presyntime - thal_cort_delay

         IF (DELTA.GE.0.d0) THEN
! AMPA part
        dexparg = delta / tauAMPA_TCR_to_deepbask 
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_deepbask(k,L)  = gAMPA_deepbask(k,L) +
     &  gAMPA_TCR_to_deepbask * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_deepbask(k,L) = gNMDA_deepbask(k,L) +
     &  gNMDA_TCR_to_deepbask * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_TCR_to_deepbask 
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_deepbask(k,L) = gNMDA_deepbask(k,L) +
     &  gNMDA_TCR_to_deepbask * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_TCR_to_deepbask  
       if (gNMDA_deepbask(k,L).gt.z)
     &  gNMDA_deepbask(k,L) = z
! end NMDA part

        ENDIF  ! condition for checking that delta >= 0.
       end do ! m
      end do ! i


c Handle nontuftRS  -> deepbask
      do i = 1, num_nontuftRS_to_deepbask
       j = map_nontuftRS_to_deepbask(i,L) ! j = presynaptic cell
       k = com_nontuftRS_to_deepbask(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_nontuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_nontuftRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_nontuftRS_to_deepbask
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_deepbask(k,L)  = gAMPA_deepbask(k,L) +
     &  gAMPA_nontuftRS_to_deepbask * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_deepbask(k,L) = gNMDA_deepbask(k,L) +
     &  gNMDA_nontuftRS_to_deepbask * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_nontuftRS_to_deepbask
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_deepbask(k,L) = gNMDA_deepbask(k,L) +
     &  gNMDA_nontuftRS_to_deepbask * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_nontuftRS_to_deepbask
       if (gNMDA_deepbask(k,L).gt.z)
     &  gNMDA_deepbask(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


         end do
c End enumeration of deepbask    
         ENDIF ! if (mod(O,how_often).eq.0) ...

! Define currents to deepbask     cells, ectopic spikes,
! tonic synaptic conductances

! Call integration routine for deepbask     cells
       CALL INTEGRATE_deepbaskx  (O, time, num_deepbask ,
     &    V_deepbask , curr_deepbask ,
     & initialize, firstcell, lastcell,
     & gAMPA_deepbask, gNMDA_deepbask, gGABA_A_deepbask,
     & Mg, 
     & gapcon_deepbask  ,totSDgj_deepbask   ,gjtable_deepbask, dt,
     &  chi_deepbask,mnaf_deepbask,mnap_deepbask,
     &  hnaf_deepbask,mkdr_deepbask,mka_deepbask,
     &  hka_deepbask,mk2_deepbask,hk2_deepbask,
     &  mkm_deepbask,mkc_deepbask,mkahp_deepbask,
     &  mcat_deepbask,hcat_deepbask,mcal_deepbask,
     &  mar_deepbask)

      if (mod(O,5).eq.0) then

c     call mpi_bcast (vax_suppyrRS  ,num_suppyrRS,
c    &    mpi_double_precision, 0, mpi_comm_world, info)
c     call mpi_bcast (vax_suppyrFRB ,num_suppyrFRB,
c    &    mpi_double_precision, 1, mpi_comm_world, info)
c     call mpi_bcast (vax_tuftIB    ,num_tuftIB  ,
c    &    mpi_double_precision, 6, mpi_comm_world, info)
c     call mpi_bcast (vax_tuftRS    ,num_tuftRS   ,
c    &    mpi_double_precision, 7, mpi_comm_world, info)

       do L = firstcell, lastcell
c           k = table_axgjcompallow_suppyrRS(1)
            k = numcomp_deepbask                  
            gj_axon_deepbask (L-firstcell+1) = V_deepbask (k,L)
       end do
  
           call mpi_allgather (    gj_axon_deepbask,
     &  maxcellspernode, mpi_double_precision,
     &      gj_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

      endif

        IF (mod(O,how_often).eq.0) then
! Set up distal axon voltage array and broadcast it.
c      do L = 1, num_deepbask    
       do L = firstcell, lastcell
        distal_axon_deepbask     (L-firstcell+1) = V_deepbask     (59,L)
       end do
  
           call mpi_allgather (distal_axon_deepbask,
     &  maxcellspernode, mpi_double_precision,
     &  distal_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

        field_1mm_local(1) = 0.d0     
        field_2mm_local(1) = 0.d0     
           call mpi_allgather (field_1mm_local,     
     &  1              , mpi_double_precision,
     &  field_1mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
           call mpi_allgather (field_2mm_local,     
     &  1              , mpi_double_precision,
     &  field_2mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
  
           ENDIF  !  if (mod(O,how_often).eq.0) ...

! END thisno for deepbask

       ELSE IF (nodecell(thisno) .eq. 'deepng   ') THEN
c deepng  

c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_deepng  
          lastcell = firstcell - 1 + ncellspernode_deepng  

          IF (mod(O,how_often).eq.0) then
c 1st set deepng    synaptic conductances to 0:

          do i = 1, numcomp_deepng  
          do j = firstcell, lastcell
         gAMPA_deepng  (i,j)    = 0.d0
         gNMDA_deepng  (i,j)    = 0.d0
         gGABA_A_deepng  (i,j)  = 0.d0
          end do
          end do

         do L = firstcell, lastcell

c Handle spinstell  -> deepng
      do i = 1, num_spinstell_to_deepng   
       j = map_spinstell_to_deepng(i,L) ! j = presynaptic cell
       k = com_spinstell_to_deepng(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_spinstell(j)  ! enumerate presyn. spikes
        presyntime = outtime_spinstell(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_spinstell_to_deepng  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_deepng(k,L)  = gAMPA_deepng(k,L) +
     &  gAMPA_spinstell_to_deepng * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_deepng(k,L) = gNMDA_deepng(k,L) +
     &  gNMDA_spinstell_to_deepng * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_spinstell_to_deepng  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_deepng(k,L) = gNMDA_deepng(k,L) +
     &  gNMDA_spinstell_to_deepng * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_spinstell_to_deepng  
       if (gNMDA_deepng(k,L).gt.z)
     &  gNMDA_deepng(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle tuftIB     -> deepng
      do i = 1, num_tuftIB_to_deepng   
       j = map_tuftIB_to_deepng(i,L) ! j = presynaptic cell
       k = com_tuftIB_to_deepng(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_tuftIB(j)  ! enumerate presyn. spikes
        presyntime = outtime_tuftIB(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_tuftIB_to_deepng  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_deepng(k,L)  = gAMPA_deepng(k,L) +
     &  gAMPA_tuftIB_to_deepng * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_deepng(k,L) = gNMDA_deepng(k,L) +
     &  gNMDA_tuftIB_to_deepng * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_tuftIB_to_deepng  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_deepng(k,L) = gNMDA_deepng(k,L) +
     &  gNMDA_tuftIB_to_deepng * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_tuftIB_to_deepng  
       if (gNMDA_deepng(k,L).gt.z)
     &  gNMDA_deepng(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle tuftRS     -> deepng
      do i = 1, num_tuftRS_to_deepng   
       j = map_tuftRS_to_deepng(i,L) ! j = presynaptic cell
       k = com_tuftRS_to_deepng(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_tuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_tuftRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_tuftRS_to_deepng  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_deepng(k,L)  = gAMPA_deepng(k,L) +
     &  gAMPA_tuftRS_to_deepng * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_deepng(k,L) = gNMDA_deepng(k,L) +
     &  gNMDA_tuftRS_to_deepng * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_tuftRS_to_deepng  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_deepng(k,L) = gNMDA_deepng(k,L) +
     &  gNMDA_tuftRS_to_deepng * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_tuftRS_to_deepng  
       if (gNMDA_deepng(k,L).gt.z)
     &  gNMDA_deepng(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle deepbask   -> deepng  
      do i = 1, num_deepbask_to_deepng      
       j = map_deepbask_to_deepng  (i,L) ! j = presynaptic cell
       k = com_deepbask_to_deepng  (i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepbask(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepbask(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepbask_to_deepng      
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_deepng  (k,L)  = gGABA_A_deepng  (k,L) +
     &  gGABA_deepbask_to_deepng   * z      
! end GABA-A part

       end do ! m
      end do ! i

c Handle deepng     -> deepng
      do i = 1, num_deepng_to_deepng    
       j = map_deepng_to_deepng(i,L) ! j = presynaptic cell
       k = com_deepng_to_deepng(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepng(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepng(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepng_to_deepng    
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_deepng(k,L)  = gGABA_A_deepng(k,L) +
     &  gGABA_deepng_to_deepng * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle TCR        -> deepng
      do i = 1, num_TCR_to_deepng 
       j = map_TCR_to_deepng(i,L) ! j = presynaptic cell
       k = com_TCR_to_deepng(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_TCR(j)  ! enumerate presyn. spikes
        presyntime = outtime_TCR(m,j)
        delta = time - presyntime - thal_cort_delay

         IF (DELTA.GE.0.d0) THEN
! AMPA part
        dexparg = delta / tauAMPA_TCR_to_deepng 
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_deepng(k,L)  = gAMPA_deepng(k,L) +
     &  gAMPA_TCR_to_deepng * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_deepng(k,L) = gNMDA_deepng(k,L) +
     &  gNMDA_TCR_to_deepng * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_TCR_to_deepng 
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_deepng(k,L) = gNMDA_deepng(k,L) +
     &  gNMDA_TCR_to_deepng * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_TCR_to_deepng  
       if (gNMDA_deepng(k,L).gt.z)
     &  gNMDA_deepng(k,L) = z
! end NMDA part

        ENDIF  ! condition for checking that delta >= 0.
       end do ! m
      end do ! i


c Handle nontuftRS  -> deepng
      do i = 1, num_nontuftRS_to_deepng
       j = map_nontuftRS_to_deepng(i,L) ! j = presynaptic cell
       k = com_nontuftRS_to_deepng(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_nontuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_nontuftRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_nontuftRS_to_deepng
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_deepng(k,L)  = gAMPA_deepng(k,L) +
     &  gAMPA_nontuftRS_to_deepng * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_deepng(k,L) = gNMDA_deepng(k,L) +
     &  gNMDA_nontuftRS_to_deepng * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_nontuftRS_to_deepng
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_deepng(k,L) = gNMDA_deepng(k,L) +
     &  gNMDA_nontuftRS_to_deepng * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_nontuftRS_to_deepng
       if (gNMDA_deepng(k,L).gt.z)
     &  gNMDA_deepng  (k,L) = z
! end NMDA part

       end do ! m
      end do ! i


         end do
c End enumeration of deepng      
         ENDIF ! if (mod(O,how_often).eq.0) ...

! Define currents to deepng       cells, ectopic spikes,
! tonic synaptic conductances

! Call integration routine for deepng     cells
       CALL INTEGRATE_deepng  (O, time, num_deepng ,
     &    V_deepng , curr_deepng ,
     & initialize, firstcell, lastcell,
     & gAMPA_deepng, gNMDA_deepng, gGABA_A_deepng,
     & Mg, 
     & gapcon_deepng  ,totSDgj_deepng   ,gjtable_deepng, dt,
     &  chi_deepng,mnaf_deepng,mnap_deepng,
     &  hnaf_deepng,mkdr_deepng,mka_deepng,
     &  hka_deepng,mk2_deepng,hk2_deepng,
     &  mkm_deepng,mkc_deepng,mkahp_deepng,
     &  mcat_deepng,hcat_deepng,mcal_deepng,
     &  mar_deepng)

      if (mod(O,5).eq.0) then


       do L = firstcell, lastcell
c           k = table_axgjcompallow_suppyrRS(1)
            k = numcomp_deepng                  
            gj_axon_deepng (L-firstcell+1) = V_deepng (k,L)
       end do
  
           call mpi_allgather (    gj_axon_deepng,
     &  maxcellspernode, mpi_double_precision,
     &      gj_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

      endif

        IF (mod(O,how_often).eq.0) then
! Set up distal axon voltage array and broadcast it.
c      do L = 1, num_deepng    
       do L = firstcell, lastcell
        distal_axon_deepng     (L-firstcell+1) = V_deepng     (59,L)
       end do
  
           call mpi_allgather (distal_axon_deepng,
     &  maxcellspernode, mpi_double_precision,
     &  distal_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

        field_1mm_local(1) = 0.d0     
        field_2mm_local(1) = 0.d0     
           call mpi_allgather (field_1mm_local,     
     &  1              , mpi_double_precision,
     &  field_1mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
           call mpi_allgather (field_2mm_local,     
     &  1              , mpi_double_precision,
     &  field_2mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
  
           ENDIF  !  if (mod(O,how_often).eq.0) ...

! END thisno for deepng  

c      ELSE IF (THISNO.EQ.10) THEN
       ELSE IF (nodecell(thisno) .eq. 'deepaxax ') THEN
c deepaxax

c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_deepaxax
          lastcell = firstcell - 1 + ncellspernode_deepaxax

        IF (mod(O,how_often).eq.0) then
c 1st set deepaxax  synaptic conductances to 0:

          do i = 1, numcomp_deepaxax
          do j = firstcell, lastcell
         gAMPA_deepaxax(i,j)    = 0.d0
         gNMDA_deepaxax(i,j)    = 0.d0
         gGABA_A_deepaxax(i,j)  = 0.d0 
          end do
          end do

         do L = firstcell, lastcell
c Handle suppyrRS   -> deepaxax
      do i = 1, num_suppyrRS_to_deepaxax  
       j = map_suppyrRS_to_deepaxax(i,L) ! j = presynaptic cell
       k = com_suppyrRS_to_deepaxax(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_suppyrRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_suppyrRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_suppyrRS_to_deepaxax  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_deepaxax(k,L)  = gAMPA_deepaxax(k,L) +
     &  gAMPA_suppyrRS_to_deepaxax * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_deepaxax(k,L) = gNMDA_deepaxax(k,L) +
     &  gNMDA_suppyrRS_to_deepaxax * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_suppyrRS_to_deepaxax  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_deepaxax(k,L) = gNMDA_deepaxax(k,L) +
     &  gNMDA_suppyrRS_to_deepaxax * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_suppyrRS_to_deepaxax  
       if (gNMDA_deepaxax(k,L).gt.z)
     &  gNMDA_deepaxax(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle suppyrFRB  -> deepaxax
      do i = 1, num_suppyrFRB_to_deepaxax  
       j = map_suppyrFRB_to_deepaxax(i,L) ! j = presynaptic cell
       k = com_suppyrFRB_to_deepaxax(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_suppyrFRB(j)  ! enumerate presyn. spikes
        presyntime = outtime_suppyrFRB(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_suppyrFRB_to_deepaxax  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_deepaxax(k,L)  = gAMPA_deepaxax(k,L) +
     &  gAMPA_suppyrFRB_to_deepaxax * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_deepaxax(k,L) = gNMDA_deepaxax(k,L) +
     &  gNMDA_suppyrFRB_to_deepaxax * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_suppyrFRB_to_deepaxax  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_deepaxax(k,L) = gNMDA_deepaxax(k,L) +
     &  gNMDA_suppyrFRB_to_deepaxax * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_suppyrFRB_to_deepaxax  
       if (gNMDA_deepaxax(k,L).gt.z)
     &  gNMDA_deepaxax(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle supLTS     -> deepaxax
      do i = 1, num_supLTS_to_deepaxax    
       j = map_supLTS_to_deepaxax(i,L) ! j = presynaptic cell
       k = com_supLTS_to_deepaxax(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supLTS(j)  ! enumerate presyn. spikes
        presyntime = outtime_supLTS(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_supLTS_to_deepaxax    
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_deepaxax(k,L)  = gGABA_A_deepaxax(k,L) +
     &  gGABA_supLTS_to_deepaxax * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle spinstell  -> deepaxax
      do i = 1, num_spinstell_to_deepaxax   
       j = map_spinstell_to_deepaxax(i,L) ! j = presynaptic cell
       k = com_spinstell_to_deepaxax(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_spinstell(j)  ! enumerate presyn. spikes
        presyntime = outtime_spinstell(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_spinstell_to_deepaxax  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_deepaxax(k,L)  = gAMPA_deepaxax(k,L) +
     &  gAMPA_spinstell_to_deepaxax * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_deepaxax(k,L) = gNMDA_deepaxax(k,L) +
     &  gNMDA_spinstell_to_deepaxax * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_spinstell_to_deepaxax  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_deepaxax(k,L) = gNMDA_deepaxax(k,L) +
     &  gNMDA_spinstell_to_deepaxax * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_spinstell_to_deepaxax  
       if (gNMDA_deepaxax(k,L).gt.z)
     &  gNMDA_deepaxax(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle tuftIB     -> deepaxax
      do i = 1, num_tuftIB_to_deepaxax   
       j = map_tuftIB_to_deepaxax(i,L) ! j = presynaptic cell
       k = com_tuftIB_to_deepaxax(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_tuftIB(j)  ! enumerate presyn. spikes
        presyntime = outtime_tuftIB(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_tuftIB_to_deepaxax  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_deepaxax(k,L)  = gAMPA_deepaxax(k,L) +
     &  gAMPA_tuftIB_to_deepaxax * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_deepaxax(k,L) = gNMDA_deepaxax(k,L) +
     &  gNMDA_tuftIB_to_deepaxax * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_tuftIB_to_deepaxax  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_deepaxax(k,L) = gNMDA_deepaxax(k,L) +
     &  gNMDA_tuftIB_to_deepaxax * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_tuftIB_to_deepaxax  
       if (gNMDA_deepaxax(k,L).gt.z)
     &  gNMDA_deepaxax(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle tuftRS     -> deepaxax
      do i = 1, num_tuftRS_to_deepaxax   
       j = map_tuftRS_to_deepaxax(i,L) ! j = presynaptic cell
       k = com_tuftRS_to_deepaxax(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_tuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_tuftRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_tuftRS_to_deepaxax  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_deepaxax(k,L)  = gAMPA_deepaxax(k,L) +
     &  gAMPA_tuftRS_to_deepaxax * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_deepaxax(k,L) = gNMDA_deepaxax(k,L) +
     &  gNMDA_tuftRS_to_deepaxax * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_tuftRS_to_deepaxax  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_deepaxax(k,L) = gNMDA_deepaxax(k,L) +
     &  gNMDA_tuftRS_to_deepaxax * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_tuftRS_to_deepaxax  
       if (gNMDA_deepaxax(k,L).gt.z)
     &  gNMDA_deepaxax(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle deepbask   -> deepaxax
      do i = 1, num_deepbask_to_deepaxax    
       j = map_deepbask_to_deepaxax(i,L) ! j = presynaptic cell
       k = com_deepbask_to_deepaxax(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepbask(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepbask(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepbask_to_deepaxax    
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_deepaxax(k,L)  = gGABA_A_deepaxax(k,L) +
     &  gGABA_deepbask_to_deepaxax * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle deepLTS    -> deepaxax
      do i = 1, num_deepLTS_to_deepaxax    
       j = map_deepLTS_to_deepaxax(i,L) ! j = presynaptic cell
       k = com_deepLTS_to_deepaxax(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepLTS(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepLTS(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepLTS_to_deepaxax    
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_deepaxax(k,L)  = gGABA_A_deepaxax(k,L) +
     &  gGABA_deepLTS_to_deepaxax * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle TCR        -> deepaxax
      do i = 1, num_TCR_to_deepaxax 
       j = map_TCR_to_deepaxax(i,L) ! j = presynaptic cell
       k = com_TCR_to_deepaxax(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_TCR(j)  ! enumerate presyn. spikes
        presyntime = outtime_TCR(m,j)
        delta = time - presyntime - thal_cort_delay

         IF (DELTA.GE.0.d0) THEN
! AMPA part
        dexparg = delta / tauAMPA_TCR_to_deepaxax 
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_deepaxax(k,L)  = gAMPA_deepaxax(k,L) +
     &  gAMPA_TCR_to_deepaxax * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_deepaxax(k,L) = gNMDA_deepaxax(k,L) +
     &  gNMDA_TCR_to_deepaxax * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_TCR_to_deepaxax 
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_deepaxax(k,L) = gNMDA_deepaxax(k,L) +
     &  gNMDA_TCR_to_deepaxax * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_TCR_to_deepaxax  
       if (gNMDA_deepaxax(k,L).gt.z)
     &  gNMDA_deepaxax(k,L) = z
! end NMDA part

        ENDIF  ! condition for checking that delta >= 0.
       end do ! m
      end do ! i


c Handle nontuftRS  -> deepaxax
      do i = 1, num_nontuftRS_to_deepaxax
       j = map_nontuftRS_to_deepaxax(i,L) ! j = presynaptic cell
       k = com_nontuftRS_to_deepaxax(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_nontuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_nontuftRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_nontuftRS_to_deepaxax
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_deepaxax(k,L)  = gAMPA_deepaxax(k,L) +
     &  gAMPA_nontuftRS_to_deepaxax * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_deepaxax(k,L) = gNMDA_deepaxax(k,L) +
     &  gNMDA_nontuftRS_to_deepaxax * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_nontuftRS_to_deepaxax
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_deepaxax(k,L) = gNMDA_deepaxax(k,L) +
     &  gNMDA_nontuftRS_to_deepaxax * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_nontuftRS_to_deepaxax
       if (gNMDA_deepaxax(k,L).gt.z)
     &  gNMDA_deepaxax(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


         end do
c End enumeration of deepaxax    
        ENDIF  !  if (mod(O,how_often).eq.0) ...

! Define currents to deepaxax     cells, ectopic spikes,
! tonic synaptic conductances

! Call integration routine for deepaxax     cells
       CALL INTEGRATE_deepaxaxx (O, time, num_deepaxax ,
     &    V_deepaxax , curr_deepaxax ,
     & initialize, firstcell, lastcell,
     & gAMPA_deepaxax, gNMDA_deepaxax, gGABA_A_deepaxax,
     & Mg, 
     & gapcon_deepaxax  ,totSDgj_deepaxax   ,gjtable_deepaxax, dt,
     &  chi_deepaxax,mnaf_deepaxax,mnap_deepaxax,
     &  hnaf_deepaxax,mkdr_deepaxax,mka_deepaxax,
     &  hka_deepaxax,mk2_deepaxax,hk2_deepaxax,
     &  mkm_deepaxax,mkc_deepaxax,mkahp_deepaxax,
     &  mcat_deepaxax,hcat_deepaxax,mcal_deepaxax,
     &  mar_deepaxax)

      if (mod(O,5).eq.0) then

c     call mpi_bcast (vax_suppyrRS  ,num_suppyrRS,
c    &    mpi_double_precision, 0, mpi_comm_world, info)
c     call mpi_bcast (vax_suppyrFRB ,num_suppyrFRB,
c    &    mpi_double_precision, 1, mpi_comm_world, info)
c     call mpi_bcast (vax_tuftIB    ,num_tuftIB  ,
c    &    mpi_double_precision, 6, mpi_comm_world, info)
c     call mpi_bcast (vax_tuftRS    ,num_tuftRS   ,
c    &    mpi_double_precision, 7, mpi_comm_world, info)

       do L = firstcell, lastcell
c           k = table_axgjcompallow_suppyrRS(1)
            k = numcomp_deepaxax                  
            gj_axon_deepaxax (L-firstcell+1) = V_deepaxax (k,L)
       end do
  
           call mpi_allgather (    gj_axon_deepaxax,
     &  maxcellspernode, mpi_double_precision,
     &      gj_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

      endif

        IF (mod(O,how_often).eq.0) then
! Set up distal axon voltage array and broadcast it.
c      do L = 1, num_deepaxax    
       do L = firstcell, lastcell
        distal_axon_deepaxax     (L-firstcell+1) = V_deepaxax     (59,L)
       end do
  
           call mpi_allgather (distal_axon_deepaxax,
     &  maxcellspernode, mpi_double_precision,
     &  distal_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

        field_1mm_local(1) = 0.d0     
        field_2mm_local(1) = 0.d0     
           call mpi_allgather (field_1mm_local,     
     &  1              , mpi_double_precision,
     &  field_1mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
           call mpi_allgather (field_2mm_local,     
     &  1              , mpi_double_precision,
     &  field_2mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
  
        ENDIF  !  if (mod(O,how_often).eq.0) ...

! END thisno for deepaxax

c      ELSE IF (THISNO.EQ.11) THEN
       ELSE IF (nodecell(thisno) .eq. 'deepLTS  ') THEN
c deepLTS

c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_deepLTS 
          lastcell = firstcell - 1 + ncellspernode_deepLTS 

       IF (mod(O,how_often).eq.0) then
c 1st set deepLTS   synaptic conductances to 0:

          do i = 1, numcomp_deepLTS
          do j = firstcell, lastcell
         gAMPA_deepLTS(i,j)     = 0.d0
         gNMDA_deepLTS(i,j)     = 0.d0
         gGABA_A_deepLTS(i,j)   = 0.d0 
          end do
          end do

         do L = firstcell, lastcell
c Handle suppyrRS   -> deepLTS
      do i = 1, num_suppyrRS_to_deepLTS   
       j = map_suppyrRS_to_deepLTS(i,L) ! j = presynaptic cell
       k = com_suppyrRS_to_deepLTS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_suppyrRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_suppyrRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_suppyrRS_to_deepLTS  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_deepLTS(k,L)  = gAMPA_deepLTS(k,L) +
     &  gAMPA_suppyrRS_to_deepLTS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_deepLTS(k,L) = gNMDA_deepLTS(k,L) +
     &  gNMDA_suppyrRS_to_deepLTS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_suppyrRS_to_deepLTS  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_deepLTS(k,L) = gNMDA_deepLTS(k,L) +
     &  gNMDA_suppyrRS_to_deepLTS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_suppyrRS_to_deepLTS  
       if (gNMDA_deepLTS(k,L).gt.z)
     &  gNMDA_deepLTS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle suppyrFRB  -> deepLTS
      do i = 1, num_suppyrFRB_to_deepLTS   
       j = map_suppyrFRB_to_deepLTS(i,L) ! j = presynaptic cell
       k = com_suppyrFRB_to_deepLTS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_suppyrFRB(j)  ! enumerate presyn. spikes
        presyntime = outtime_suppyrFRB(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_suppyrFRB_to_deepLTS  
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_deepLTS(k,L)  = gAMPA_deepLTS(k,L) +
     &  gAMPA_suppyrFRB_to_deepLTS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_deepLTS(k,L) = gNMDA_deepLTS(k,L) +
     &  gNMDA_suppyrFRB_to_deepLTS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_suppyrFRB_to_deepLTS  
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_deepLTS(k,L) = gNMDA_deepLTS(k,L) +
     &  gNMDA_suppyrFRB_to_deepLTS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_suppyrFRB_to_deepLTS  
       if (gNMDA_deepLTS(k,L).gt.z)
     &  gNMDA_deepLTS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle supLTS     -> deepLTS
      do i = 1, num_supLTS_to_deepLTS     
       j = map_supLTS_to_deepLTS(i,L) ! j = presynaptic cell
       k = com_supLTS_to_deepLTS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_supLTS(j)  ! enumerate presyn. spikes
        presyntime = outtime_supLTS(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_supLTS_to_deepLTS     
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_deepLTS(k,L)  = gGABA_A_deepLTS(k,L) +
     &  gGABA_supLTS_to_deepLTS * z      
! end GABA-A part

       end do ! m
      end do ! i

c Handle spinstell  -> deepLTS
      do i = 1, num_spinstell_to_deepLTS    
       j = map_spinstell_to_deepLTS(i,L) ! j = presynaptic cell
       k = com_spinstell_to_deepLTS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_spinstell(j)  ! enumerate presyn. spikes
        presyntime = outtime_spinstell(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_spinstell_to_deepLTS   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_deepLTS(k,L)  = gAMPA_deepLTS(k,L) +
     &  gAMPA_spinstell_to_deepLTS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_deepLTS(k,L) = gNMDA_deepLTS(k,L) +
     &  gNMDA_spinstell_to_deepLTS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_spinstell_to_deepLTS   
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_deepLTS(k,L) = gNMDA_deepLTS(k,L) +
     &  gNMDA_spinstell_to_deepLTS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_spinstell_to_deepLTS  
       if (gNMDA_deepLTS(k,L).gt.z)
     &  gNMDA_deepLTS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle tuftIB     -> deepLTS
      do i = 1, num_tuftIB_to_deepLTS    
       j = map_tuftIB_to_deepLTS(i,L) ! j = presynaptic cell
       k = com_tuftIB_to_deepLTS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_tuftIB(j)  ! enumerate presyn. spikes
        presyntime = outtime_tuftIB(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_tuftIB_to_deepLTS   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_deepLTS(k,L)  = gAMPA_deepLTS(k,L) +
     &  gAMPA_tuftIB_to_deepLTS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_deepLTS(k,L) = gNMDA_deepLTS(k,L) +
     &  gNMDA_tuftIB_to_deepLTS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_tuftIB_to_deepLTS   
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_deepLTS(k,L) = gNMDA_deepLTS(k,L) +
     &  gNMDA_tuftIB_to_deepLTS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_tuftIB_to_deepLTS   
       if (gNMDA_deepLTS(k,L).gt.z)
     &  gNMDA_deepLTS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle tuftRS     -> deepLTS
      do i = 1, num_tuftRS_to_deepLTS    
       j = map_tuftRS_to_deepLTS(i,L) ! j = presynaptic cell
       k = com_tuftRS_to_deepLTS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_tuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_tuftRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_tuftRS_to_deepLTS   
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_deepLTS(k,L)  = gAMPA_deepLTS(k,L) +
     &  gAMPA_tuftRS_to_deepLTS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_deepLTS(k,L) = gNMDA_deepLTS(k,L) +
     &  gNMDA_tuftRS_to_deepLTS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_tuftRS_to_deepLTS   
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_deepLTS(k,L) = gNMDA_deepLTS(k,L) +
     &  gNMDA_tuftRS_to_deepLTS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_tuftRS_to_deepLTS   
       if (gNMDA_deepLTS(k,L).gt.z)
     &  gNMDA_deepLTS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle deepbask   -> deepLTS
      do i = 1, num_deepbask_to_deepLTS     
       j = map_deepbask_to_deepLTS(i,L) ! j = presynaptic cell
       k = com_deepbask_to_deepLTS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepbask(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepbask(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepbask_to_deepLTS     
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_deepLTS(k,L)  = gGABA_A_deepLTS(k,L) +
     &  gGABA_deepbask_to_deepLTS * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle deepLTS    -> deepLTS
      do i = 1, num_deepLTS_to_deepLTS     
       j = map_deepLTS_to_deepLTS(i,L) ! j = presynaptic cell
       k = com_deepLTS_to_deepLTS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_deepLTS(j)  ! enumerate presyn. spikes
        presyntime = outtime_deepLTS(m,j)
        delta = time - presyntime

! GABA-A part
        dexparg = delta / tauGABA_deepLTS_to_deepLTS     
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gGABA_A_deepLTS(k,L)  = gGABA_A_deepLTS(k,L) +
     &  gGABA_deepLTS_to_deepLTS * z      
! end GABA-A part

       end do ! m
      end do ! i


c Handle nontuftRS  -> deepLTS
      do i = 1, num_nontuftRS_to_deepLTS
       j = map_nontuftRS_to_deepLTS(i,L) ! j = presynaptic cell
       k = com_nontuftRS_to_deepLTS(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_nontuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_nontuftRS(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_nontuftRS_to_deepLTS
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_deepLTS(k,L)  = gAMPA_deepLTS(k,L) +
     &  gAMPA_nontuftRS_to_deepLTS * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_deepLTS(k,L) = gNMDA_deepLTS(k,L) +
     &  gNMDA_nontuftRS_to_deepLTS * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_nontuftRS_to_deepLTS 
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_deepLTS(k,L) = gNMDA_deepLTS(k,L) +
     &  gNMDA_nontuftRS_to_deepLTS * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_nontuftRS_to_deepLTS
       if (gNMDA_deepLTS(k,L).gt.z)
     &  gNMDA_deepLTS(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


         end do
c End enumeration of deepLTS     
         ENDIF  !  if (mod(O,how_often).eq.0) ...

! Define currents to deepLTS      cells, ectopic spikes,
! tonic synaptic conductances

! Call integration routine for deepLTS      cells
       CALL INTEGRATE_deepLTSx  (O, time, num_deepLTS  ,
     &    V_deepLTS  , curr_deepLTS  ,
     & initialize, firstcell, lastcell,
     & gAMPA_deepLTS  , gNMDA_deepLTS  , gGABA_A_deepLTS  ,
     & Mg, 
     & gapcon_deepLTS  ,totSDgj_deepLTS  ,gjtable_deepLTS  , dt,
     &  chi_deepLTS,mnaf_deepLTS,mnap_deepLTS,
     &  hnaf_deepLTS,mkdr_deepLTS,mka_deepLTS,
     &  hka_deepLTS,mk2_deepLTS,hk2_deepLTS,
     &  mkm_deepLTS,mkc_deepLTS,mkahp_deepLTS,
     &  mcat_deepLTS,hcat_deepLTS,mcal_deepLTS,
     &  mar_deepLTS)

      if (mod(O,5).eq.0) then

c     call mpi_bcast (vax_suppyrRS  ,num_suppyrRS,
c    &    mpi_double_precision, 0, mpi_comm_world, info)
c     call mpi_bcast (vax_suppyrFRB ,num_suppyrFRB,
c    &    mpi_double_precision, 1, mpi_comm_world, info)
c     call mpi_bcast (vax_tuftIB    ,num_tuftIB  ,
c    &    mpi_double_precision, 6, mpi_comm_world, info)
c     call mpi_bcast (vax_tuftRS    ,num_tuftRS   ,
c    &    mpi_double_precision, 7, mpi_comm_world, info)

       do L = firstcell, lastcell
c           k = table_axgjcompallow_suppyrRS(1)
            k = numcomp_deepLTS                   
            gj_axon_deepLTS  (L-firstcell+1) = V_deepLTS  (k,L)
       end do
  
           call mpi_allgather (    gj_axon_deepLTS ,
     &  maxcellspernode, mpi_double_precision,
     &      gj_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

      endif

        IF (mod(O,how_often).eq.0) then
! Set up distal axon voltage array and broadcast it.
c      do L = 1, num_deepLTS     
       do L = firstcell, lastcell
        distal_axon_deepLTS      (L-firstcell+1) = V_deepLTS      (59,L)
       end do
  
           call mpi_allgather (distal_axon_deepLTS, 
     &  maxcellspernode, mpi_double_precision,
     &  distal_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

        field_1mm_local(1) = 0.d0     
        field_2mm_local(1) = 0.d0     
           call mpi_allgather (field_1mm_local,     
     &  1              , mpi_double_precision,
     &  field_1mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
           call mpi_allgather (field_2mm_local,     
     &  1              , mpi_double_precision,
     &  field_2mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
  
        ENDIF  !  if (mod(O,how_often).eq.0) ...

! END thisno for deepLTS

c      ELSE IF (THISNO.EQ.12) THEN
       ELSE IF (nodecell(thisno) .eq. 'TCR      ') THEN
c TCR

c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_TCR     
          lastcell = firstcell - 1 + ncellspernode_TCR     

        IF (mod(O,how_often).eq.0) then
c 1st set TCR synaptic conductances to 0:

          do i = 1, numcomp_TCR
          do j = firstcell, lastcell
         gAMPA_TCR(i,j)         = 0.d0 
         gNMDA_TCR(i,j)         = 0.d0
         gGABA_A_TCR(i,j)       = 0.d0 
         gGABA_B_TCR(i,j)       = 0.d0 
          end do
          end do

         do L = firstcell, lastcell
c Handle nRT       -> TCR
      do i = 1, num_nRT_to_TCR     
       j = map_nRT_to_TCR(i,L) ! j = presynaptic cell
       k = com_nRT_to_TCR(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_nRT(j)  ! enumerate presyn. spikes
        presyntime = outtime_nRT(m,j)
        delta = time - presyntime
        k0 = nint (10.d0 * delta) ! time, in units of 0.1 ms, to pass to otis_table
        if (k0 .gt. 50000) k = 50000  ! limit on size of otis_table

! GABA-A part
        dexparg1 = delta / tauGABA1_nRT_to_TCR     
c note that dexparg1 = MINUS the actual arg. to dexp
         if (dexparg1.le.5.d0) then
          z1 = dexptablesmall (int(dexparg1*1000.d0))
         else if (dexparg1.le.100.d0) then
          z1 = dexptablebig (int(dexparg1*10.d0))
         else
          z1 = 0.d0
         endif

        dexparg2 = delta / tauGABA2_nRT_to_TCR     
c note that dexparg2 = MINUS the actual arg. to dexp
         if (dexparg2.le.5.d0) then
          z2 = dexptablesmall (int(dexparg2*1000.d0))
         else if (dexparg2.le.100.d0) then
          z2 = dexptablebig (int(dexparg2*10.d0))
         else
          z2 = 0.d0
         endif

      gGABA_A_TCR(k,L)  = gGABA_A_TCR(k,L) +
     &  gGABA_nRT_to_TCR(j) * (0.625d0 * z1 + 0.375d0 * z2) 
! end GABA-A part


      gGABA_B_TCR(k,L) = gGABA_B_TCR(k,L) +
     &   gGABAB_nRT_to_TCR * otis_table(k0)
! end GABA-B part
       end do ! m
      end do ! i


c Handle nontuftRS -> TCR
      do i = 1, num_nontuftRS_to_TCR
       j = map_nontuftRS_to_TCR(i,L) ! j = presynaptic cell
       k = com_nontuftRS_to_TCR(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_nontuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_nontuftRS(m,j)
        delta = time - presyntime - cort_thal_delay

         IF (DELTA.GE.0.d0) THEN
! AMPA part
        dexparg = delta / tauAMPA_nontuftRS_to_TCR
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_TCR(k,L)  = gAMPA_TCR(k,L) +
     &  gAMPA_nontuftRS_to_TCR * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_TCR(k,L) = gNMDA_TCR(k,L) +
     &  gNMDA_nontuftRS_to_TCR * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_nontuftRS_to_TCR
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_TCR(k,L) = gNMDA_TCR(k,L) +
     &  gNMDA_nontuftRS_to_TCR * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_nontuftRS_to_TCR 
       if (gNMDA_TCR(k,L).gt.z)
     &  gNMDA_TCR(k,L) = z
! end NMDA part

        ENDIF  ! condition for checking that delta >= 0.
       end do ! m
      end do ! i


         end do
c End enumeration of TCR         
          ENDIF  !  if (mod(O,how_often).eq.0) ...

! Define currents to TCR          cells, ectopic spikes,
! tonic synaptic conductances

      if (mod(O,200).eq.0) then
       call durand(seed,num_TCR     ,ranvec_TCR     ) 
        do L = firstcell, lastcell
         if ((ranvec_TCR     (L).gt.0.d0).and.
     &     (ranvec_TCR     (L).le.noisepe_TCR     )) then
          curr_TCR     (135,L) = 0.4d0
          ectr_TCR      = ectr_TCR      + 1
         else
          curr_TCR     (135,L) = 0.d0
         endif 
        end do
      endif

c       GOTO 9144 ! SKIP TCR INTEGRATION IN ISOLATED CTX
! Call integration routine for TCR          cells
       CALL INTEGRATE_tcrxB     (O, time, num_tcr      ,
     &    V_tcr      , curr_tcr      ,
     & initialize, firstcell, lastcell,
     & gAMPA_tcr      , gNMDA_tcr      , gGABA_A_tcr      ,
     & gGABA_B_tcr, Mg, 
     & gapcon_tcr      ,totaxgj_tcr      ,gjtable_tcr      , dt,
     &  chi_tcr,mnaf_tcr,mnap_tcr,
     &  hnaf_tcr,mkdr_tcr,mka_tcr,
     &  hka_tcr,mk2_tcr,hk2_tcr,
     &  mkm_tcr,mkc_tcr,mkahp_tcr,
     &  mcat_tcr,hcat_tcr,mcal_tcr,
     &  mar_tcr)
9144    CONTINUE

      if (mod(O,5).eq.0) then

c     call mpi_bcast (vax_suppyrRS  ,num_suppyrRS,
c    &    mpi_double_precision, 0, mpi_comm_world, info)
c     call mpi_bcast (vax_suppyrFRB ,num_suppyrFRB,
c    &    mpi_double_precision, 1, mpi_comm_world, info)
c     call mpi_bcast (vax_tuftIB    ,num_tuftIB  ,
c    &    mpi_double_precision, 6, mpi_comm_world, info)
c     call mpi_bcast (vax_tuftRS    ,num_tuftRS   ,
c    &    mpi_double_precision, 7, mpi_comm_world, info)

       do L = firstcell, lastcell
            k = table_axgjcompallow_TCR(1)
            gj_axon_TCR      (L-firstcell+1) = V_TCR      (k,L)
       end do
  
           call mpi_allgather (    gj_axon_TCR     ,
     &  maxcellspernode, mpi_double_precision,
     &      gj_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

      endif

         IF (mod(O,how_often).eq.0) then
! Set up distal axon voltage array and broadcast it.
c      do L = 1, num_TCR         
       do L = firstcell, lastcell
        distal_axon_TCR  (L-firstcell+1) = V_TCR          (135,L)
       end do
  
           call mpi_allgather (distal_axon_TCR,     
     &  maxcellspernode, mpi_double_precision,
     &  distal_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

        field_1mm_local(1) = 0.d0       
        field_2mm_local(1) = 0.d0     
           call mpi_allgather (field_1mm_local,     
     &  1              , mpi_double_precision,
     &  field_1mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
           call mpi_allgather (field_2mm_local,     
     &  1              , mpi_double_precision,
     &  field_2mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
  
        ENDIF  !  if (mod(O,how_often).eq.0) ...

! END thisno for TCR

c      ELSE IF (THISNO.EQ.13) THEN
       ELSE IF (nodecell(thisno) .eq. 'nRT      ') THEN
c nRT

c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_nRT     
          lastcell = firstcell - 1 + ncellspernode_nRT     

        IF (mod(O,how_often).eq.0) then
c 1st set nRT synaptic conductances to 0:

          do i = 1, numcomp_nRT
          do j = firstcell, lastcell
         gAMPA_nRT(i,j)         = 0.d0 
         gNMDA_nRT(i,j)         = 0.d0
         gGABA_A_nRT(i,j)       = 0.d0
         gGABA_B_nRT(i,j)       = 0.d0
          end do
          end do

         do L = firstcell, lastcell
c Handle TCR        -> nRT
      do i = 1, num_TCR_to_nRT
       j = map_TCR_to_nRT(i,L) ! j = presynaptic cell
       k = com_TCR_to_nRT(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_TCR(j)  ! enumerate presyn. spikes
        presyntime = outtime_TCR(m,j)
        delta = time - presyntime

! AMPA part
        dexparg = delta / tauAMPA_TCR_to_nRT
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_nRT(k,L)  = gAMPA_nRT(k,L) +
     &  gAMPA_TCR_to_nRT * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_nRT(k,L) = gNMDA_nRT(k,L) +
     &  gNMDA_TCR_to_nRT * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_TCR_to_nRT 
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_nRT(k,L) = gNMDA_nRT(k,L) +
     &  gNMDA_TCR_to_nRT * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_TCR_to_nRT
       if (gNMDA_nRT(k,L).gt.z)
     &  gNMDA_nRT(k,L) = z
! end NMDA part

       end do ! m
      end do ! i


c Handle nRT        -> nRT
      do i = 1, num_nRT_to_nRT     
       j = map_nRT_to_nRT(i,L) ! j = presynaptic cell
       k = com_nRT_to_nRT(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_nRT(j)  ! enumerate presyn. spikes
        presyntime = outtime_nRT(m,j)
        delta = time - presyntime
        k0 = nint (10.d0 * delta) ! time, in units of 0.1 ms, to pass to otis_table
        if (k0 .gt. 50000) k = 50000  ! limit on size of otis_table

! GABA-A part
        dexparg1 = delta / tauGABA1_nRT_to_nRT     
c note that dexparg1 = MINUS the actual arg. to dexp
         if (dexparg1.le.5.d0) then
          z1 = dexptablesmall (int(dexparg1*1000.d0))
         else if (dexparg1.le.100.d0) then
          z1 = dexptablebig (int(dexparg1*10.d0))
         else
          z1 = 0.d0
         endif

        dexparg2 = delta / tauGABA2_nRT_to_nRT     
c note that dexparg2 = MINUS the actual arg. to dexp
         if (dexparg2.le.5.d0) then
          z2 = dexptablesmall (int(dexparg2*1000.d0))
         else if (dexparg2.le.100.d0) then
          z2 = dexptablebig (int(dexparg2*10.d0))
         else
          z2 = 0.d0
         endif

      gGABA_A_nRT(k,L)  = gGABA_A_nRT(k,L) +
     &  gGABA_nRT_to_nRT * (0.56d0 * z1 + 0.44d0 * z2) 
! end GABA-A part

      gGABA_B_nRT(k,L) = gGABA_B_nRT(k,L) +
     &   gGABAB_nRT_to_nRT * otis_table(k0)

! end GABA-B part
       end do ! m
      end do ! i


c Handle nontuftRS  -> nRT
      do i = 1, num_nontuftRS_to_nRT
       j = map_nontuftRS_to_nRT(i,L) ! j = presynaptic cell
       k = com_nontuftRS_to_nRT(i,L) ! k = comp. on postsyn. cell

       do m = 1, outctr_nontuftRS(j)  ! enumerate presyn. spikes
        presyntime = outtime_nontuftRS(m,j)
        delta = time - presyntime - cort_thal_delay

         IF (DELTA.GE.0.d0) THEN
! AMPA part
        dexparg = delta / tauAMPA_nontuftRS_to_nRT
c note that dexparg = MINUS the actual arg. to dexp
         if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif

      gAMPA_nRT(k,L)  = gAMPA_nRT(k,L) +
     &  gAMPA_nontuftRS_to_nRT * delta * z      
! end AMPA part

! NMDA part
        if (delta.le.5.d0) then
       gNMDA_nRT(k,L) = gNMDA_nRT(k,L) +
     &  gNMDA_nontuftRS_to_nRT * delta * 0.2d0
        else
       dexparg = (delta - 5.d0)/tauNMDA_nontuftRS_to_nRT
          if (dexparg.le.5.d0) then
          z = dexptablesmall (int(dexparg*1000.d0))
         else if (dexparg.le.100.d0) then
          z = dexptablebig (int(dexparg*10.d0))
         else
          z = 0.d0
         endif
       gNMDA_nRT(k,L) = gNMDA_nRT(k,L) +
     &  gNMDA_nontuftRS_to_nRT * z
        endif
c Test for NMDA saturation
       z = NMDA_saturation_fact * gNMDA_nontuftRS_to_nRT 
       if (gNMDA_nRT(k,L).gt.z)
     &  gNMDA_nRT(k,L) = z
! end NMDA part

        ENDIF  ! condition for checking that delta >= 0.
       end do ! m
      end do ! i


         end do
c End enumeration of nRT         
        ENDIF  !  if (mod(O,how_often).eq.0) ...

! Define currents to nRT          cells, ectopic spikes,
! tonic synaptic conductances

! Call integration routine for nRT          cells
       CALL INTEGRATE_nrtxB      (O, time, num_nRT      ,
     &    V_nRT      , curr_nRT      ,
     & initialize, firstcell, lastcell,
     & gAMPA_nRT      , gNMDA_nRT      , gGABA_A_nRT      ,
     & gGABA_B_nRT, Mg, 
     & gapcon_nRT      ,totSDgj_nRT      ,gjtable_nRT      , dt,
     &  chi_nRT,mnaf_nRT,mnap_nRT,
     &  hnaf_nRT,mkdr_nRT,mka_nRT,
     &  hka_nRT,mk2_nRT,hk2_nRT,
     &  mkm_nRT,mkc_nRT,mkahp_nRT,
     &  mcat_nRT,hcat_nRT,mcal_nRT,
     &  mar_nRT)

      if (mod(O,5).eq.0) then

c     call mpi_bcast (vax_suppyrRS  ,num_suppyrRS,
c    &    mpi_double_precision, 0, mpi_comm_world, info)
c     call mpi_bcast (vax_suppyrFRB ,num_suppyrFRB,
c    &    mpi_double_precision, 1, mpi_comm_world, info)
c     call mpi_bcast (vax_tuftIB    ,num_tuftIB  ,
c    &    mpi_double_precision, 6, mpi_comm_world, info)
c     call mpi_bcast (vax_tuftRS    ,num_tuftRS   ,
c    &    mpi_double_precision, 7, mpi_comm_world, info)

       do L = firstcell, lastcell
c           k = table_axgjcompallow_suppyrRS(1)
            k = numcomp_nRT                      
            gj_axon_nRT      (L-firstcell+1) = V_nRT      (k,L)
       end do
  
           call mpi_allgather (    gj_axon_nRT     ,
     &  maxcellspernode, mpi_double_precision,
     &      gj_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

      endif

         IF (mod(O,how_often).eq.0) then
! Set up distal axon voltage array and broadcast it.
c      do L = 1, num_nRT         
       do L = firstcell, lastcell
        distal_axon_nRT  (L-firstcell+1) = V_nRT          (59,L)
       end do
  
           call mpi_allgather (distal_axon_nRT,      
     &  maxcellspernode, mpi_double_precision,
     &  distal_axon_global,maxcellspernode,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)

        field_1mm_local(1) = 0.d0      
        field_2mm_local(1) = 0.d0       
           call mpi_allgather (field_1mm_local,     
     &  1              , mpi_double_precision,
     &  field_1mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
           call mpi_allgather (field_2mm_local,     
     &  1              , mpi_double_precision,
     &  field_2mm_global  , 1             ,mpi_double_precision,
     &                      MPI_COMM_WORLD, info)
  
         ENDIF  !  if (mod(O,how_often).eq.0) ...

! END thisno for nRT

       ENDIF  ! if (mod(O,how_often).eq.0) then ...

! Update distal axon vectors, then outctr's and outtime tables.
! This code is common to all the nodes.
! Some of this section adapted from supergj.f
c     IF (mod(O,how_often).eq.0) then
      IF (mod(O,  5      ).eq.0) then ! Necessary because gj data also
!  being updated, not just synaptic
c Construct distal axon vectors, taking into account the structure of
c distal_axon_global: let m = maxcellspernode;
c then nodesfor_suppyrRS segments, each m entries long;
c following this, nodesfor_suppyrFRB segments, each m entries long; etc....
! Do the same for voltages at sites of possible axonal gj.

            ictr = 0 ! will keep track of which segment in distal_axon_global

            j = table_axgjcompallow_suppyrRS (1)
            do k = 1, nodesfor_suppyrRS
              ictr = ictr + 1
              ioffset = (ictr - 1) * maxcellspernode + 1 ! offset in distal_axon_global
              m = 1 + (k-1) * ncellspernode_suppyrRS  ! offset in ldistal_axon_suppyrRS
        do i = m, m + ncellspernode_suppyrRS - 1 
         ldistal_axon_suppyrRS(i   ) = distal_axon_global(ioffset+i-m)
         v_suppyrRS  (j,i)          =     gj_axon_global(ioffset+i-m)
        end do
             end do

            j = table_axgjcompallow_suppyrFRB(1)
            do k = 1, nodesfor_suppyrFRB
              ictr = ictr + 1
              ioffset = (ictr - 1) * maxcellspernode + 1 ! offset in distal_axon_global
              m = 1 + (k-1) * ncellspernode_suppyrFRB ! offset in ldistal_axon_suppyrFRB
        do i = m, m + ncellspernode_suppyrFRB - 1 
         ldistal_axon_suppyrFRB(i   ) = distal_axon_global(ioffset+i-m)
         v_suppyrFRB (j,i)           =     gj_axon_global(ioffset+i-m)
        end do
             end do

            j = numcomp_supbask
            do k = 1, nodesfor_supbask  
              ictr = ictr + 1
              ioffset = (ictr - 1) * maxcellspernode + 1 ! offset in distal_axon_global
              m = 1 + (k-1) * ncellspernode_supbask   ! offset in ldistal_axon_supbask  
        do i = m, m + ncellspernode_supbask   - 1 
         ldistal_axon_supbask  (i   ) = distal_axon_global(ioffset+i-m)
         v_supbask   (j,i)           =     gj_axon_global(ioffset+i-m)
        end do
             end do

            j = numcomp_supng
            do k = 1, nodesfor_supng  
              ictr = ictr + 1
              ioffset = (ictr - 1) * maxcellspernode + 1 ! offset in distal_axon_global
              m = 1 + (k-1) * ncellspernode_supng   ! offset in ldistal_axon_supng  
        do i = m, m + ncellspernode_supng   - 1 
         ldistal_axon_supng  (i   ) = distal_axon_global(ioffset+i-m)
         v_supng   (j,i)           =     gj_axon_global(ioffset+i-m)
        end do
             end do

            j = numcomp_supaxax
            do k = 1, nodesfor_supaxax  
              ictr = ictr + 1
              ioffset = (ictr - 1) * maxcellspernode + 1 ! offset in distal_axon_global
              m = 1 + (k-1) * ncellspernode_supaxax   ! offset in ldistal_axon_supaxax  
        do i = m, m + ncellspernode_supaxax   - 1 
         ldistal_axon_supaxax  (i   ) = distal_axon_global(ioffset+i-m)
         v_supaxax   (j,i)           =     gj_axon_global(ioffset+i-m)
        end do
             end do

            j = numcomp_supLTS
            do k = 1, nodesfor_supLTS   
              ictr = ictr + 1
              ioffset = (ictr - 1) * maxcellspernode + 1 ! offset in distal_axon_global
              m = 1 + (k-1) * ncellspernode_supLTS    ! offset in ldistal_axon_supLTS   
        do i = m, m + ncellspernode_supLTS    - 1 
         ldistal_axon_supLTS   (i   ) = distal_axon_global(ioffset+i-m)
         v_supLTS    (j,i)           =     gj_axon_global(ioffset+i-m)
        end do
             end do

            j = table_axgjcompallow_spinstell(1)
            do k = 1, nodesfor_spinstell
              ictr = ictr + 1
              ioffset = (ictr - 1) * maxcellspernode + 1 ! offset in distal_axon_global
              m = 1 + (k-1) * ncellspernode_spinstell ! offset in ldistal_axon_spinstell
        do i = m, m + ncellspernode_spinstell - 1 
         ldistal_axon_spinstell(i   ) = distal_axon_global(ioffset+i-m)
         v_spinstell (j,i)           =     gj_axon_global(ioffset+i-m)
        end do
             end do

            j = table_axgjcompallow_tuftIB   (1)
            do k = 1, nodesfor_tuftIB   
              ictr = ictr + 1
              ioffset = (ictr - 1) * maxcellspernode + 1 ! offset in distal_axon_global
              m = 1 + (k-1) * ncellspernode_tuftIB    ! offset in ldistal_axon_tuftIB   
        do i = m, m + ncellspernode_tuftIB    - 1 
         ldistal_axon_tuftIB   (i   ) = distal_axon_global(ioffset+i-m)
         v_tuftIB    (j,i)           =     gj_axon_global(ioffset+i-m)
        end do
             end do

            j = table_axgjcompallow_tuftRS   (1)
            do k = 1, nodesfor_tuftRS   
              ictr = ictr + 1
              ioffset = (ictr - 1) * maxcellspernode + 1 ! offset in distal_axon_global
              m = 1 + (k-1) * ncellspernode_tuftRS    ! offset in ldistal_axon_tuftRS   
        do i = m, m + ncellspernode_tuftRS    - 1 
         ldistal_axon_tuftRS   (i   ) = distal_axon_global(ioffset+i-m)
         v_tuftRS    (j,i)           =     gj_axon_global(ioffset+i-m)
        end do
             end do

            j = table_axgjcompallow_nontuftRS(1)
            do k = 1, nodesfor_nontuftRS   
              ictr = ictr + 1
              ioffset = (ictr - 1) * maxcellspernode + 1 ! offset in distal_axon_global
              m = 1 + (k-1) * ncellspernode_nontuftRS    ! offset in ldistal_axon_nontuftRS   
        do i = m, m + ncellspernode_nontuftRS    - 1 
         ldistal_axon_nontuftRS  (i ) = distal_axon_global(ioffset+i-m)
         v_nontuftRS (j,i)           =     gj_axon_global(ioffset+i-m)
        end do
             end do

            j = numcomp_deepbask
            do k = 1, nodesfor_deepbask    
              ictr = ictr + 1
              ioffset = (ictr - 1) * maxcellspernode + 1 ! offset in distal_axon_global
              m = 1 + (k-1) * ncellspernode_deepbask     ! offset in ldistal_axon_deepbask    
        do i = m, m + ncellspernode_deepbask     - 1 
         ldistal_axon_deepbask   (i ) = distal_axon_global(ioffset+i-m)
         v_deepbask  (j,i)           =     gj_axon_global(ioffset+i-m)
        end do
             end do

            j = numcomp_deepng
            do k = 1, nodesfor_deepng    
              ictr = ictr + 1
              ioffset = (ictr - 1) * maxcellspernode + 1 ! offset in distal_axon_global
              m = 1 + (k-1) * ncellspernode_deepng     ! offset in ldistal_axon_deepng    
        do i = m, m + ncellspernode_deepng     - 1 
         ldistal_axon_deepng   (i ) = distal_axon_global(ioffset+i-m)
         v_deepng  (j,i)           =     gj_axon_global(ioffset+i-m)
        end do
             end do

            j = numcomp_deepaxax
            do k = 1, nodesfor_deepaxax    
              ictr = ictr + 1
              ioffset = (ictr - 1) * maxcellspernode + 1 ! offset in distal_axon_global
              m = 1 + (k-1) * ncellspernode_deepaxax     ! offset in ldistal_axon_deepaxax    
        do i = m, m + ncellspernode_deepaxax     - 1 
         ldistal_axon_deepaxax   (i ) = distal_axon_global(ioffset+i-m)
         v_deepaxax  (j,i)           =     gj_axon_global(ioffset+i-m)
        end do
             end do

            j = numcomp_deepLTS
            do k = 1, nodesfor_deepLTS     
              ictr = ictr + 1
              ioffset = (ictr - 1) * maxcellspernode + 1 ! offset in distal_axon_global
              m = 1 + (k-1) * ncellspernode_deepLTS      ! offset in ldistal_axon_deepLTS     
        do i = m, m + ncellspernode_deepLTS      - 1 
         ldistal_axon_deepLTS    (i ) = distal_axon_global(ioffset+i-m)
         v_deepLTS   (j,i)           =     gj_axon_global(ioffset+i-m)
        end do
             end do

            j = table_axgjcompallow_TCR      (1)
            do k = 1, nodesfor_TCR         
              ictr = ictr + 1
              ioffset = (ictr - 1) * maxcellspernode + 1 ! offset in distal_axon_global
              m = 1 + (k-1) * ncellspernode_TCR          ! offset in ldistal_axon_TCR         
        do i = m, m + ncellspernode_TCR          - 1 
         ldistal_axon_TCR        (i ) = distal_axon_global(ioffset+i-m)
         v_TCR       (j,i)           =     gj_axon_global(ioffset+i-m)
        end do
             end do

            j = numcomp_nRT
            do k = 1, nodesfor_nRT         
              ictr = ictr + 1
              ioffset = (ictr - 1) * maxcellspernode + 1 ! offset in distal_axon_global
              m = 1 + (k-1) * ncellspernode_nRT          ! offset in ldistal_axon_nRT         
        do i = m, m + ncellspernode_nRT          - 1 
         ldistal_axon_nRT        (i ) = distal_axon_global(ioffset+i-m)
         v_nRT       (j,i)           =     gj_axon_global(ioffset+i-m)
        end do
             end do
c End updating of distal axon vectors.

       do L = 1, num_suppyrRS
	 if (ldistal_axon_suppyrRS(L).ge.0.d0) then
c with threshold = 0, means axonal spike must be overshooting.
	  if (outctr_suppyrRS(L).eq.0) then
	    outctr_suppyrRS(L) = 1
	    outtime_suppyrRS(1,L) = time
          else
      if ((time-outtime_suppyrRS(outctr_suppyrRS(L),L))
     &   .gt. axon_refrac_time) then
	     outctr_suppyrRS(L) = outctr_suppyrRS(L) + 1
	     outtime_suppyrRS (outctr_suppyrRS(L),L) = time
            endif
          endif
	 endif
       end do  ! do L = 1, num_suppyrRS

       do L = 1, num_suppyrFRB
	 if (ldistal_axon_suppyrFRB(L).ge.0.d0) then
c with threshold = 0, means axonal spike must be overshooting.
	  if (outctr_suppyrFRB(L).eq.0) then
	    outctr_suppyrFRB(L) = 1
	    outtime_suppyrFRB(1,L) = time
          else
      if ((time-outtime_suppyrFRB(outctr_suppyrFRB(L),L))
     &   .gt. axon_refrac_time) then
	     outctr_suppyrFRB(L) = outctr_suppyrFRB(L) + 1
	     outtime_suppyrFRB (outctr_suppyrFRB(L),L) = time
            endif
          endif
	 endif
       end do  ! do L = 1, num_suppyrFRB

       do L = 1, num_supbask   
	 if (ldistal_axon_supbask(L).ge.0.d0) then
c with threshold = 0, means axonal spike must be overshooting.
	  if (outctr_supbask(L).eq.0) then
	    outctr_supbask(L) = 1
	    outtime_supbask(1,L) = time
          else
      if ((time-outtime_supbask(outctr_supbask(L),L))
     &   .gt. axon_refrac_time) then
	     outctr_supbask(L) = outctr_supbask(L) + 1
	     outtime_supbask (outctr_supbask(L),L) = time
            endif
          endif
	 endif
       end do  ! do L = 1, num_supbask  

       do L = 1, num_supng   
	 if (ldistal_axon_supng(L).ge.0.d0) then
c with threshold = 0, means axonal spike must be overshooting.
	  if (outctr_supng(L).eq.0) then
	    outctr_supng(L) = 1
	    outtime_supng(1,L) = time
          else
      if ((time-outtime_supng(outctr_supng(L),L))
     &   .gt. axon_refrac_time) then
	     outctr_supng(L) = outctr_supng(L) + 1
	     outtime_supng (outctr_supng(L),L) = time
            endif
          endif
	 endif
       end do  ! do L = 1, num_supng  

       do L = 1, num_supaxax   
	 if (ldistal_axon_supaxax(L).ge.0.d0) then
c with threshold = 0, means axonal spike must be overshooting.
	  if (outctr_supaxax(L).eq.0) then
	    outctr_supaxax(L) = 1
	    outtime_supaxax(1,L) = time
          else
      if ((time-outtime_supaxax(outctr_supaxax(L),L))
     &   .gt. axon_refrac_time) then
	     outctr_supaxax(L) = outctr_supaxax(L) + 1
	     outtime_supaxax (outctr_supaxax(L),L) = time
            endif
          endif
	 endif
       end do  ! do L = 1, num_supaxax  

       do L = 1, num_supLTS    
	 if (ldistal_axon_supLTS(L).ge.0.d0) then
c with threshold = 0, means axonal spike must be overshooting.
	  if (outctr_supLTS(L).eq.0) then
	    outctr_supLTS(L) = 1
	    outtime_supLTS(1,L) = time
          else
      if ((time-outtime_supLTS(outctr_supLTS(L),L))
     &   .gt. axon_refrac_time) then
	     outctr_supLTS(L) = outctr_supLTS(L) + 1
	     outtime_supLTS (outctr_supLTS(L),L) = time
            endif
          endif
	 endif
       end do  ! do L = 1, num_supLTS  

       do L = 1, num_spinstell 
	 if (ldistal_axon_spinstell(L).ge.0.d0) then
c with threshold = 0, means axonal spike must be overshooting.
	  if (outctr_spinstell(L).eq.0) then
	    outctr_spinstell(L) = 1
	    outtime_spinstell(1,L) = time
          else
      if ((time-outtime_spinstell(outctr_spinstell(L),L))
     &   .gt. axon_refrac_time) then
	     outctr_spinstell(L) = outctr_spinstell(L) + 1
	     outtime_spinstell (outctr_spinstell(L),L) = time
            endif
          endif
	 endif
       end do  ! do L = 1, num_spinstell

       do L = 1, num_tuftIB    
	 if (ldistal_axon_tuftIB(L).ge.0.d0) then
c with threshold = 0, means axonal spike must be overshooting.
	  if (outctr_tuftIB(L).eq.0) then
	    outctr_tuftIB(L) = 1
	    outtime_tuftIB(1,L) = time
          else
      if ((time-outtime_tuftIB(outctr_tuftIB(L),L))
     &   .gt. axon_refrac_time) then
	     outctr_tuftIB(L) = outctr_tuftIB(L) + 1
	     outtime_tuftIB (outctr_tuftIB(L),L) = time
            endif
          endif
	 endif
       end do  ! do L = 1, num_tuftIB   

       do L = 1, num_tuftRS    
	 if (ldistal_axon_tuftRS(L).ge.0.d0) then
c with threshold = 0, means axonal spike must be overshooting.
	  if (outctr_tuftRS(L).eq.0) then
	    outctr_tuftRS(L) = 1
	    outtime_tuftRS(1,L) = time
          else
      if ((time-outtime_tuftRS(outctr_tuftRS(L),L))
     &   .gt. axon_refrac_time) then
	     outctr_tuftRS(L) = outctr_tuftRS(L) + 1
	     outtime_tuftRS (outctr_tuftRS(L),L) = time
            endif
          endif
	 endif
       end do  ! do L = 1, num_tuftRS   

       do L = 1, num_nontuftRS    
	 if (ldistal_axon_nontuftRS(L).ge.0.d0) then
c with threshold = 0, means axonal spike must be overshooting.
	  if (outctr_nontuftRS(L).eq.0) then
	    outctr_nontuftRS(L) = 1
	    outtime_nontuftRS(1,L) = time
          else
      if ((time-outtime_nontuftRS(outctr_nontuftRS(L),L))
     &   .gt. axon_refrac_time) then
	     outctr_nontuftRS(L) = outctr_nontuftRS(L) + 1
	     outtime_nontuftRS (outctr_nontuftRS(L),L) = time
            endif
          endif
	 endif
       end do  ! do L = 1, num_nontuftRS   

       do L = 1, num_deepbask     
	 if (ldistal_axon_deepbask(L).ge.0.d0) then
c with threshold = 0, means axonal spike must be overshooting.
	  if (outctr_deepbask(L).eq.0) then
	    outctr_deepbask(L) = 1
	    outtime_deepbask(1,L) = time
          else
      if ((time-outtime_deepbask(outctr_deepbask(L),L))
     &   .gt. axon_refrac_time) then
	     outctr_deepbask(L) = outctr_deepbask(L) + 1
	     outtime_deepbask (outctr_deepbask(L),L) = time
            endif
          endif
	 endif
       end do  ! do L = 1, num_deepbask   

       do L = 1, num_deepng     
	 if (ldistal_axon_deepng(L).ge.0.d0) then
c with threshold = 0, means axonal spike must be overshooting.
	  if (outctr_deepng(L).eq.0) then
	    outctr_deepng(L) = 1
	    outtime_deepng(1,L) = time
          else
      if ((time-outtime_deepng(outctr_deepng(L),L))
     &   .gt. axon_refrac_time) then
	     outctr_deepng(L) = outctr_deepng(L) + 1
	     outtime_deepng (outctr_deepng(L),L) = time
            endif
          endif
	 endif
       end do  ! do L = 1, num_deepng   

       do L = 1, num_deepaxax     
	 if (ldistal_axon_deepaxax(L).ge.0.d0) then
c with threshold = 0, means axonal spike must be overshooting.
	  if (outctr_deepaxax(L).eq.0) then
	    outctr_deepaxax(L) = 1
	    outtime_deepaxax(1,L) = time
          else
      if ((time-outtime_deepaxax(outctr_deepaxax(L),L))
     &   .gt. axon_refrac_time) then
	     outctr_deepaxax(L) = outctr_deepaxax(L) + 1
	     outtime_deepaxax (outctr_deepaxax(L),L) = time
            endif
          endif
	 endif
       end do  ! do L = 1, num_deepaxax   

       do L = 1, num_deepLTS      
	 if (ldistal_axon_deepLTS(L).ge.0.d0) then
c with threshold = 0, means axonal spike must be overshooting.
	  if (outctr_deepLTS(L).eq.0) then
	    outctr_deepLTS(L) = 1
	    outtime_deepLTS(1,L) = time
          else
      if ((time-outtime_deepLTS(outctr_deepLTS(L),L))
     &   .gt. axon_refrac_time) then
	     outctr_deepLTS(L) = outctr_deepLTS(L) + 1
	     outtime_deepLTS (outctr_deepLTS(L),L) = time
            endif
          endif
	 endif
       end do  ! do L = 1, num_deepLTS   

       do L = 1, num_TCR      
	 if (ldistal_axon_TCR(L).ge.0.d0) then
c with threshold = 0, means axonal spike must be overshooting.
	  if (outctr_TCR(L).eq.0) then
	    outctr_TCR(L) = 1
	    outtime_TCR(1,L) = time
          else
      if ((time-outtime_TCR(outctr_TCR(L),L))
     &   .gt. axon_refrac_time) then
	     outctr_TCR(L) = outctr_TCR(L) + 1
	     outtime_TCR (outctr_TCR(L),L) = time
            endif
          endif
	 endif
       end do  ! do L = 1, num_TCR   

       do L = 1, num_nRT      
	 if (ldistal_axon_nRT(L).ge.0.d0) then
c with threshold = 0, means axonal spike must be overshooting.
	  if (outctr_nRT(L).eq.0) then
	    outctr_nRT(L) = 1
	    outtime_nRT(1,L) = time
          else
      if ((time-outtime_nRT(outctr_nRT(L),L))
     &   .gt. axon_refrac_time) then
	     outctr_nRT(L) = outctr_nRT(L) + 1
	     outtime_nRT (outctr_nRT(L),L) = time
            endif
          endif
	 endif
       end do  ! do L = 1, num_nRT   

       field_1mm_tot = 0.d0
       field_2mm_tot = 0.d0
        do i = 1, numnodes
         field_1mm_tot = field_1mm_tot + field_1mm_global(i)
         field_2mm_tot = field_2mm_tot + field_2mm_global(i)
        end do

      ENDIF  ! if (mod(O,how_often).eq.0) ...
       ! CHANGED to if (mod(O,5).eq.0)...
! End updating outctr's and outtime tables, and computing fields

! Set up output data to be written
       if (mod(O, 50) == 0) then
c      if (thisno.eq.0) then
       IF (nodecell(thisno) .eq. 'suppyrRS ') THEN
c suppyrRS
c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_suppyrRS
          lastcell = firstcell - 1 + ncellspernode_suppyrRS

        outrcd( 1) = time
        outrcd( 2) = v_suppyrRS(1,firstcell+1)
        outrcd( 3) = v_suppyrRS(numcomp_suppyrRS,firstcell+1)
        outrcd( 4) = v_suppyrRS(43,firstcell+1)
         z = 0.d0
          do i = firstcell, lastcell
           z = z - v_suppyrRS(1,i)
          end do
        outrcd( 5) = z / dble(lastcell - firstcell + 1) ! - av. cell somata 
         z = 0.d0
          do i = 1, numcomp_suppyrRS
           z = z + gAMPA_suppyrRS(i,firstcell+1)
          end do
        outrcd( 6) = z * 1000.d0 ! total AMPA cell 2 
         z = 0.d0
          do i = 1, numcomp_suppyrRS
           z = z + gNMDA_suppyrRS(i,firstcell+1)
          end do
        outrcd( 7) = z * 1000.d0 ! total NMDA cell 2 
         z = 0.d0
          do i = 1, numcomp_suppyrRS
           z = z + gGABA_A_suppyrRS(i,firstcell+1)
          end do
        outrcd( 8) = z * 1000.d0 ! total GABA-A, cell 2 
         z = 0.d0
          do i = 1, numcomp_suppyrRS
           z = z + gGABA_B_suppyrRS(i,firstcell+1)
          end do
        outrcd( 9) = z * 1000.d0 ! total GABA-B, cell 2 
        outrcd(10) = v_suppyrRS(1,firstcell+2)
        outrcd(11) = v_suppyrRS(1,firstcell+3)
          z = 0.d0
          do i = firstcell, lastcell
           if(v_suppyrRS(numcomp_suppyrRS,i) .gt. 0.d0) z = z + 1.d0
          end do
        outrcd(12) = z   
        outrcd(13) = field_1mm_tot     
        outrcd(14) = field_2mm_tot     

            if (place(thisno).eq.1) then
      OPEN(11,FILE='spikewaveS96.suppyrRS')
      WRITE (11,FMT='(14F10.4)') (OUTRCD(I),I=1,14)
            end if

c      else if (thisno.eq.1) then
       else IF (nodecell(thisno) .eq. 'suppyrFRB') THEN
c suppyrFRB
c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_suppyrFRB
          lastcell = firstcell - 1 + ncellspernode_suppyrFRB

        outrcd( 1) = time
        outrcd( 2) = v_suppyrFRB(1,firstcell+1)
        outrcd( 3) = v_suppyrFRB(numcomp_suppyrFRB,firstcell+1)
        outrcd( 4) = v_suppyrFRB(43,firstcell+1)
         z = 0.d0
          do i = firstcell, lastcell
           z = z - v_suppyrFRB(1,i)
          end do
        outrcd( 5) = z / dble(lastcell - firstcell + 1) ! - av. cell somata 
         z = 0.d0
          do i = 1, numcomp_suppyrFRB
           z = z + gAMPA_suppyrFRB(i,firstcell+1)
          end do
        outrcd( 6) = z * 1000.d0 ! total AMPA cell 2 
         z = 0.d0
          do i = 1, numcomp_suppyrFRB
           z = z + gNMDA_suppyrFRB(i,firstcell+1)
          end do
        outrcd( 7) = z * 1000.d0 ! total NMDA cell 2 
         z = 0.d0
          do i = 1, numcomp_suppyrFRB
           z = z + gGABA_A_suppyrFRB(i,firstcell+1)
          end do
        outrcd( 8) = z * 1000.d0 ! total GABA-A, cell 2 
         z = 0.d0
          do i = 1, numcomp_suppyrFRB
           z = z + gGABA_B_suppyrFRB(i,firstcell+1)
          end do
        outrcd( 9) = z * 1000.d0 ! total GABA-A, cell 2 
        outrcd(10) = v_suppyrFRB(1,firstcell+2)
        outrcd(11) = v_suppyrFRB(1,firstcell+3)
        outrcd(12) = field_1mm_tot      
        outrcd(13) = field_2mm_tot      

        if (place(thisno).eq.1) then
      OPEN(12,FILE='spikewaveS96.suppyrFRB')
      WRITE (12,FMT='(13F10.4)') (OUTRCD(I),I=1,13)
        endif

c      else if (thisno.eq.2) then
       else IF (nodecell(thisno) .eq. 'supbask  ') THEN
c supbask 
c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_supbask 
          lastcell = firstcell - 1 + ncellspernode_supbask 

        outrcd( 1) = time
        outrcd( 2) = v_supbask  (1,firstcell+1)
        outrcd( 3) = v_supbask  (numcomp_supbask,firstcell+1)
        outrcd( 4) = v_supbask  (43,firstcell+1)
         z = 0.d0
          do i = firstcell, lastcell
           z = z - v_supbask(1,i)
          end do
        outrcd( 5) = z / dble(lastcell - firstcell + 1  ) ! - av. cell somata 
         z = 0.d0
          do i = 1, numcomp_supbask   
           z = z + gAMPA_supbask  (i,firstcell+1)
          end do
        outrcd( 6) = z * 1000.d0 ! total AMPA cell 2 
         z = 0.d0
          do i = 1, numcomp_supbask   
           z = z + gNMDA_supbask  (i,firstcell+1)
          end do
        outrcd( 7) = z * 1000.d0 ! total NMDA cell 2 
         z = 0.d0
          do i = 1, numcomp_supbask  
           z = z + gGABA_A_supbask  (i,firstcell+1)
          end do
        outrcd( 8) = z * 1000.d0 ! total GABA-A, cell 2 
        outrcd( 9) = v_supbask  (1,firstcell+2)
        outrcd(10) = v_supbask  (1,firstcell+3)
        outrcd(11) = field_1mm_tot      
        outrcd(12) = field_2mm_tot      
         if (place(thisno).eq.1) then
      OPEN(13,FILE='spikewaveS96.supbask')
      WRITE (13,FMT='(12F10.4)') (OUTRCD(I),I=1,12)
         endif

       else IF (nodecell(thisno) .eq. 'supng  ') THEN
c supng 
c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_supng 
          lastcell = firstcell - 1 + ncellspernode_supng 

        outrcd( 1) = time
        outrcd( 2) = v_supng  (1,firstcell+1)
        outrcd( 3) = v_supng  (numcomp_supng,firstcell+1)
        outrcd( 4) = v_supng  (43,firstcell+1)
         z = 0.d0
          do i = firstcell, lastcell
           z = z - v_supng(1,i)
          end do
        outrcd( 5) = z / dble(lastcell - firstcell + 1  ) ! - av. cell somata 
         z = 0.d0
          do i = 1, numcomp_supng   
           z = z + gAMPA_supng  (i,firstcell+1)
          end do
        outrcd( 6) = z * 1000.d0 ! total AMPA cell 2 
         z = 0.d0
          do i = 1, numcomp_supng   
           z = z + gNMDA_supng  (i,firstcell+1)
          end do
        outrcd( 7) = z * 1000.d0 ! total NMDA cell 2 
         z = 0.d0
          do i = 1, numcomp_supng  
           z = z + gGABA_A_supng  (i,firstcell+1)
          end do
        outrcd( 8) = z * 1000.d0 ! total GABA-A, cell 2 
        outrcd( 9) = v_supng  (1,firstcell+2)
        outrcd(10) = v_supng  (1,firstcell+3)
        outrcd(11) = field_1mm_tot      
        outrcd(12) = field_2mm_tot      
         if (place(thisno).eq.1) then
      OPEN(33,FILE='spikewaveS96.supng')
      WRITE (33,FMT='(12F10.4)') (OUTRCD(I),I=1,12)
         endif

c      else if (thisno.eq.3) then
       else IF (nodecell(thisno) .eq. 'supaxax  ') THEN
c supaxax 
c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_supaxax 
          lastcell = firstcell - 1 + ncellspernode_supaxax 

        outrcd( 1) = time
        outrcd( 2) = v_supaxax  (1,firstcell+1)
        outrcd( 3) = v_supaxax  (numcomp_supaxax  ,firstcell+1)
        outrcd( 4) = v_supaxax  (43,firstcell+1)
         z = 0.d0
          do i = firstcell, lastcell
           z = z - v_supaxax(1,i)
          end do
        outrcd( 5) = z / dble(lastcell-firstcell+1) !  -av. cell somata 
         z = 0.d0
          do i = 1, numcomp_supaxax  
           z = z + gAMPA_supaxax  (i,firstcell+1)
          end do
        outrcd( 6) = z * 1000.d0 ! total AMPA cell 2 
         z = 0.d0
          do i = 1, numcomp_supaxax  
           z = z + gNMDA_supaxax  (i,firstcell+1)
          end do
        outrcd( 7) = z * 1000.d0 ! total NMDA cell 2 
         z = 0.d0
          do i = 1, numcomp_supaxax  
           z = z + gGABA_A_supaxax  (i,firstcell+1)
          end do
        outrcd( 8) = z * 1000.d0 ! total GABA-A, cell 2 
        outrcd( 9) = v_supaxax  (1,firstcell+2)
        outrcd(10) = v_supaxax  (1,firstcell+3)
        outrcd(11) = field_1mm_tot
        outrcd(12) = field_2mm_tot
          if (place(thisno).eq.1) then
      OPEN(14,FILE='spikewaveS96.supaxax')
      WRITE (14,FMT='(12F10.4)') (OUTRCD(I),I=1,12)
          endif

c      else if (thisno.eq.4) then
       else IF (nodecell(thisno) .eq. 'supLTS   ') THEN
c supLTS  
c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_supLTS  
          lastcell = firstcell - 1 + ncellspernode_supLTS  

        outrcd( 1) = time
        outrcd( 2) = v_supLTS   (1,firstcell+1)
        outrcd( 3) = v_supLTS   (numcomp_supLTS   ,firstcell+1)
        outrcd( 4) = v_supLTS   (43,firstcell+1)
         z = 0.d0
          do i = firstcell, lastcell
           z = z - v_supLTS(1,i)
          end do
        outrcd( 5) = z / dble(lastcell-firstcell+1) !  -av. cell somata 
         z = 0.d0
          do i = 1, numcomp_supLTS   
           z = z + gAMPA_supLTS   (i,firstcell+1)
          end do
        outrcd( 6) = z * 1000.d0 ! total AMPA cell 2 
         z = 0.d0
          do i = 1, numcomp_supLTS   
           z = z + gNMDA_supLTS   (i,firstcell+1)
          end do
        outrcd( 7) = z * 1000.d0 ! total NMDA cell 2 
         z = 0.d0
          do i = 1, numcomp_supLTS   
           z = z + gGABA_A_supLTS   (i,firstcell+1)
          end do
        outrcd( 8) = z * 1000.d0 ! total GABA-A, cell 2 
        outrcd( 9) = v_supLTS   (1,firstcell+2)
        outrcd(10) = v_supLTS   (1,firstcell+3)
        outrcd(11) = field_1mm_tot
        outrcd(12) = field_2mm_tot
         if (place(thisno).eq.1) then
      OPEN(15,FILE='spikewaveS96.supLTS')
      WRITE (15,FMT='(12F10.4)') (OUTRCD(I),I=1,12)
         endif

c      else if (thisno.eq.5) then
       else IF (nodecell(thisno) .eq. 'spinstell') THEN
c spinstell
c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_spinstell
          lastcell = firstcell - 1 + ncellspernode_spinstell

        outrcd( 1) = time
        outrcd( 2) = v_spinstell(1,firstcell+1)
        outrcd( 3) = v_spinstell(numcomp_spinstell,firstcell+1)
        outrcd( 4) = v_spinstell(43,firstcell+1)
         z = 0.d0
          do i = firstcell, lastcell
           z = z - v_spinstell(1,i)
          end do
        outrcd( 5) = z / dble(lastcell-firstcell+1) !  -av. cell somata 
         z = 0.d0
          do i = 1, numcomp_spinstell
           z = z + gAMPA_spinstell(i,firstcell+1)
          end do
        outrcd( 6) = z * 1000.d0 ! total AMPA cell 1 
         z = 0.d0
          do i = 1, numcomp_spinstell
           z = z + gNMDA_spinstell(i,firstcell+1)
          end do
        outrcd( 7) = z * 1000.d0 ! total NMDA cell 1 
         z = 0.d0
          do i = 1, numcomp_spinstell
           z = z + gGABA_A_spinstell(i,firstcell+1)
          end do
        outrcd( 8) = z * 1000.d0 ! total GABA-A, cell 1 
         z = 0.d0
          do i = 1, numcomp_spinstell
           z = z + gGABA_B_spinstell(i,firstcell+1)
          end do
        outrcd( 9) = z * 1000.d0 ! total GABA-B, cell 1 
        outrcd(10) = v_spinstell(1,firstcell+2)
        outrcd(11) = v_spinstell(1,firstcell+3)

        outrcd(12) = field_1mm_tot    
        outrcd(13) = field_2mm_tot

          if (place(thisno).eq.1) then
      OPEN(16,FILE='spikewaveS96.spinstell')
      WRITE (16,FMT='(13F10.4)') (OUTRCD(I),I=1,13)
          endif

c      do i = 1, num_spinstell
c       if ((time.ge.300.d0).and.(v_spinstell(1,i).gt.10.d0)) then
c          OPEN(30,FILE='spikewaveS96.spinstell.raster')
c          WRITE(30,FMT='(2F10.4)') time, dble(i)
c       endif
c      end do

c      else if (thisno.eq.6) then
       else IF (nodecell(thisno) .eq. 'tuftIB   ') THEN
c tuftIB  
c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_tuftIB  
          lastcell = firstcell - 1 + ncellspernode_tuftIB  

        outrcd( 1) = time
        outrcd( 2) = v_tuftIB   (1,firstcell+1)
        outrcd( 3) = v_tuftIB   (numcomp_tuftIB   ,firstcell+1)
        outrcd( 4) = v_tuftIB   (43,firstcell+1)
         z = 0.d0
          do i = firstcell, lastcell
           z = z - v_tuftIB(1,i)
          end do
        outrcd( 5) = z / dble(lastcell-firstcell+1) !  -av. cell somata 
         z = 0.d0
          do i = 1, numcomp_tuftIB   
           z = z + gAMPA_tuftIB   (i,firstcell+1)
          end do
        outrcd( 6) = z * 1000.d0 ! total AMPA cell 2 
         z = 0.d0
          do i = 1, numcomp_tuftIB   
           z = z + gNMDA_tuftIB   (i,firstcell+1)
          end do
        outrcd( 7) = z * 1000.d0 ! total NMDA cell 2 
         z = 0.d0
          do i = 1, numcomp_tuftIB   
           z = z + gGABA_A_tuftIB   (i,firstcell+1)
          end do
        outrcd( 8) = z * 1000.d0 ! total GABA-A, cell 2 
         z = 0.d0
          do i = 1, numcomp_tuftIB   
           z = z + gGABA_B_tuftIB   (i,firstcell+1)
          end do
        outrcd( 9) = z * 1000.d0 ! total GABA-B, cell 2 
        outrcd(10) = v_tuftIB   (1,firstcell+2)
        outrcd(11) = v_tuftIB   (1,firstcell+3)
        outrcd(12) = field_1mm_tot   
        outrcd(13) = field_2mm_tot   
        outrcd(14) = v_tuftIB   (1,firstcell+4)
        outrcd(15) = v_tuftIB   (numcomp_tuftIB   ,firstcell+4)
          z = 0.d0
        do L = 1, num_tuftIB
          if (ldistal_axon_tuftIB(L).ge.0.d0) z = z + 1.d0
        end do
        outrcd(16) = z ! should be number of distal tuftIB axons overshooting
        outrcd(17) = v_tuftIB (1,firstcell + 5)
        outrcd(18) = v_tuftIB (1,firstcell + 6)
        outrcd(19) = v_tuftIB (1,firstcell + 7)
c       outrcd(20) = v_tuftIB (1,firstcell + 8)
        outrcd(20) = 1000.d0 * noisepe_tuftIB 
          if (place(thisno).eq.1) then
      OPEN(17,FILE='spikewaveS96.tuftIB')
      WRITE (17,FMT='(20F10.4)') (OUTRCD(I),I=1,20)
          else
c           write(6,9091) 'tuftIB', thisno, time, v_tuftIB(1,firstcell),
c    &            v_tuftIB(1,lastcell)
9091        format(a6,i4,3f10.4)
          endif

c      else if (thisno.eq.7) then
       else IF (nodecell(thisno) .eq. 'tuftRS   ') THEN
c tuftRS  
c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_tuftRS  
          lastcell = firstcell - 1 + ncellspernode_tuftRS  

        outrcd( 1) = time
        outrcd( 2) = v_tuftRS   (1,firstcell+1)
        outrcd( 3) = v_tuftRS   (numcomp_tuftRS   ,firstcell+1)
        outrcd( 4) = v_tuftRS   (43,firstcell+1)
         z = 0.d0
          do i = firstcell, lastcell
           z = z - v_tuftRS(1,i)
          end do
        outrcd( 5) = z / dble(lastcell-firstcell+1) !  -av. cell somata 
         z = 0.d0
          do i = 1, numcomp_tuftRS   
           z = z + gAMPA_tuftRS   (i,firstcell+1)
          end do
        outrcd( 6) = z * 1000.d0 ! total AMPA cell 2 
         z = 0.d0
          do i = 1, numcomp_tuftRS   
           z = z + gNMDA_tuftRS   (i,firstcell+1)
          end do
        outrcd( 7) = z * 1000.d0 ! total NMDA cell 2 
         z = 0.d0
          do i = 1, numcomp_tuftRS   
           z = z + gGABA_A_tuftRS   (i,firstcell+1)
          end do
        outrcd( 8) = z * 1000.d0 ! total GABA-A, cell 2 
         z = 0.d0
          do i = 1, numcomp_tuftRS   
           z = z + gGABA_B_tuftRS   (i,firstcell+1)
          end do
        outrcd( 9) = z * 1000.d0 ! total GABA-B, cell 2 
        outrcd(10) = v_tuftRS   (1,firstcell+2)
        outrcd(11) = v_tuftRS   (1,firstcell+3)
        outrcd(12) = field_1mm_tot   
        outrcd(13) = field_2mm_tot    
          if (place(thisno).eq.1) then
      OPEN(18,FILE='spikewaveS96.tuftRS')
      WRITE (18,FMT='(13F10.4)') (OUTRCD(I),I=1,13)
          end if

c      else if (thisno.eq.8) then
       else IF (nodecell(thisno) .eq. 'nontuftRS') THEN
c nontuftRS
c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_nontuftRS
          lastcell = firstcell - 1 + ncellspernode_nontuftRS

        outrcd( 1) = time
        outrcd( 2) = v_nontuftRS(1,firstcell+1)
        outrcd( 3) = v_nontuftRS(numcomp_nontuftRS,firstcell+1)
        outrcd( 4) = v_nontuftRS(43,firstcell+1)
         z = 0.d0
          do i = firstcell, lastcell
           z = z - v_nontuftRS(1,i)
          end do
        outrcd( 5) = z / dble(lastcell-firstcell+1) !  -av. cell somata 
         z = 0.d0
          do i = 1, numcomp_nontuftRS
           z = z + gAMPA_nontuftRS(i,firstcell+1)
          end do
        outrcd( 6) = z * 1000.d0 ! total AMPA cell 2 
         z = 0.d0
          do i = 1, numcomp_nontuftRS
           z = z + gNMDA_nontuftRS(i,firstcell+1)
          end do
        outrcd( 7) = z * 1000.d0 ! total NMDA cell 2 
         z = 0.d0
          do i = 1, numcomp_nontuftRS
           z = z + gGABA_A_nontuftRS(i,firstcell+1)
          end do
        outrcd( 8) = z * 1000.d0 ! total GABA-A, cell 2 
         z = 0.d0
          do i = 1, numcomp_nontuftRS
           z = z + gGABA_B_nontuftRS(i,firstcell+1)
          end do
        outrcd( 9) = z * 1000.d0 ! total GABA-B, cell 2 
        outrcd(10) = v_nontuftRS(1,firstcell+2)
        outrcd(11) = v_nontuftRS(1,firstcell+3)
        outrcd(12) = field_1mm_tot      
        outrcd(13) = field_2mm_tot       
        outrcd(14) = v_nontuftRS(1,lastcell     -2)
        outrcd(15) = v_nontuftRS(1,lastcell     -1)
        outrcd(16) = v_nontuftRS(1,lastcell     )
          if (place(thisno).eq.1) then
      OPEN(19,FILE='spikewaveS96.nontuftRS')
      WRITE (19,FMT='(16F10.4)') (OUTRCD(I),I=1,16)
          else
c      write(6,9092) 'nontuftRS',thisno,time,v_nontuftRS(1,firstcell),
c    &            v_nontuftRS(1,lastcell)
9092        format(a9,i4,3f10.4)
          endif

c      else if (thisno.eq.9) then
       else IF (nodecell(thisno) .eq. 'deepbask ') THEN
c deepbask 
c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_deepbask
          lastcell = firstcell - 1 + ncellspernode_deepbask

        outrcd( 1) = time
        outrcd( 2) = v_deepbask (1,firstcell+1)
        outrcd( 3) = v_deepbask (numcomp_deepbask ,firstcell+1)
        outrcd( 4) = v_deepbask (43,firstcell+1)
         z = 0.d0
          do i = firstcell, lastcell
           z = z - v_deepbask(1,i)
          end do
        outrcd( 5) = z / dble(lastcell-firstcell+1) !  -av. cell somata 
         z = 0.d0
          do i = 1, numcomp_deepbask 
           z = z + gAMPA_deepbask (i,firstcell+1)
          end do
        outrcd( 6) = z * 1000.d0 ! total AMPA cell 2 
         z = 0.d0
          do i = 1, numcomp_deepbask 
           z = z + gNMDA_deepbask (i,firstcell+1)
          end do
        outrcd( 7) = z * 1000.d0 ! total NMDA cell 2 
         z = 0.d0
          do i = 1, numcomp_deepbask 
           z = z + gGABA_A_deepbask (i,firstcell+1)
          end do
        outrcd( 8) = z * 1000.d0 ! total GABA-A, cell 2 
        outrcd( 9) = v_deepbask (1,firstcell+2)
        outrcd(10) = v_deepbask (1,firstcell+3)
        outrcd(11) = field_1mm_tot
        outrcd(12) = field_2mm_tot
           if (place(thisno).eq.1) then
      OPEN(20,FILE='spikewaveS96.deepbask')
      WRITE (20,FMT='(12F10.4)') (OUTRCD(I),I=1,12)
           endif

c      do i = 1, num_deepbask 
c       if ((time.ge.300.d0).and.(v_deepbask (1,i).gt.10.d0)) then
c          OPEN(31,FILE='spikewaveS96.deepbask.raster')
c          WRITE(31,FMT='(2F10.4)') time, dble(i)
c       endif
c      end do

       else IF (nodecell(thisno) .eq. 'deepng ') THEN
c deepng 
c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_deepng
          lastcell = firstcell - 1 + ncellspernode_deepng

        outrcd( 1) = time
        outrcd( 2) = v_deepng (1,firstcell+1)
        outrcd( 3) = v_deepng (numcomp_deepng ,firstcell+1)
        outrcd( 4) = v_deepng (43,firstcell+1)
         z = 0.d0
          do i = firstcell, lastcell
           z = z - v_deepng(1,i)
          end do
        outrcd( 5) = z / dble(lastcell-firstcell+1) !  -av. cell somata 
         z = 0.d0
          do i = 1, numcomp_deepng 
           z = z + gAMPA_deepng (i,firstcell+1)
          end do
        outrcd( 6) = z * 1000.d0 ! total AMPA cell 2 
         z = 0.d0
          do i = 1, numcomp_deepng 
           z = z + gNMDA_deepng (i,firstcell+1)
          end do
        outrcd( 7) = z * 1000.d0 ! total NMDA cell 2 
         z = 0.d0
          do i = 1, numcomp_deepng 
           z = z + gGABA_A_deepng (i,firstcell+1)
          end do
        outrcd( 8) = z * 1000.d0 ! total GABA-A, cell 2 
        outrcd( 9) = v_deepng (1,firstcell+2)
        outrcd(10) = v_deepng (1,firstcell+3)
        outrcd(11) = field_1mm_tot
        outrcd(12) = field_2mm_tot
           if (place(thisno).eq.1) then
      OPEN(34,FILE='spikewaveS96.deepng')
      WRITE (34,FMT='(12F10.4)') (OUTRCD(I),I=1,12)
           endif


c      else if (thisno.eq.10) then
       else IF (nodecell(thisno) .eq. 'deepaxax ') THEN
c deepaxax
c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_deepaxax
          lastcell = firstcell - 1 + ncellspernode_deepaxax

        outrcd( 1) = time
        outrcd( 2) = v_deepaxax (1,firstcell+1)
        outrcd( 3) = v_deepaxax (numcomp_deepaxax ,firstcell+1)
        outrcd( 4) = v_deepaxax (43,firstcell+1)
         z = 0.d0
          do i = firstcell, lastcell
           z = z - v_deepaxax(1,i)
          end do
        outrcd( 5) = z / dble(lastcell-firstcell+1) !  -av. cell somata 
         z = 0.d0
          do i = 1, numcomp_deepaxax 
           z = z + gAMPA_deepaxax (i,firstcell+1)
          end do
        outrcd( 6) = z * 1000.d0 ! total AMPA cell 2 
         z = 0.d0
          do i = 1, numcomp_deepaxax 
           z = z + gNMDA_deepaxax (i,firstcell+1)
          end do
        outrcd( 7) = z * 1000.d0 ! total NMDA cell 2 
         z = 0.d0
          do i = 1, numcomp_deepaxax 
           z = z + gGABA_A_deepaxax (i,firstcell+1)
          end do
        outrcd( 8) = z * 1000.d0 ! total GABA-A, cell 2 
        outrcd( 9) = v_deepaxax (1,firstcell+2)
        outrcd(10) = v_deepaxax (1,firstcell+3)
        outrcd(11) = field_1mm_tot
        outrcd(12) = field_2mm_tot
           if (place(thisno).eq.1) then
      OPEN(21,FILE='spikewaveS96.deepaxax')
      WRITE (21,FMT='(12F10.4)') (OUTRCD(I),I=1,12)
           endif

c      else if (thisno.eq.11) then
       else IF (nodecell(thisno) .eq. 'deepLTS  ') THEN
c deepLTS 
c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_deepLTS 
          lastcell = firstcell - 1 + ncellspernode_deepLTS 

        outrcd( 1) = time
        outrcd( 2) = v_deepLTS  (1,firstcell+1)
        outrcd( 3) = v_deepLTS  (numcomp_deepLTS  ,firstcell+1)
        outrcd( 4) = v_deepLTS  (43,firstcell+1)
         z = 0.d0
          do i = firstcell, lastcell
           z = z - v_deepLTS(1,i)
          end do
        outrcd( 5) = z / dble(lastcell-firstcell+1) !  -av. cell somata 
         z = 0.d0
          do i = 1, numcomp_deepLTS  
           z = z + gAMPA_deepLTS  (i,firstcell+1)
          end do
        outrcd( 6) = z * 1000.d0 ! total AMPA cell 2 
         z = 0.d0
          do i = 1, numcomp_deepLTS   
           z = z + gNMDA_deepLTS  (i,firstcell+1)
          end do
        outrcd( 7) = z * 1000.d0 ! total NMDA cell 2 
         z = 0.d0
          do i = 1, numcomp_deepLTS  
           z = z + gGABA_A_deepLTS  (i,firstcell+1)
          end do
        outrcd( 8) = z * 1000.d0 ! total GABA-A, cell 2 
        outrcd( 9) = v_deepLTS  (1,firstcell+2)
        outrcd(10) = v_deepLTS  (1,firstcell+3)
        outrcd(11) = field_1mm_tot
        outrcd(12) = field_2mm_tot
         if (place(thisno).eq.1) then
      OPEN(22,FILE='spikewaveS96.deepLTS')
      WRITE (22,FMT='(12F10.4)') (OUTRCD(I),I=1,12)
         endif

c      else if (thisno.eq.12) then
       else IF (nodecell(thisno) .eq. 'TCR      ') THEN
c TCR      
c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_TCR     
          lastcell = firstcell - 1 + ncellspernode_TCR      

        outrcd( 1) = time
        outrcd( 2) = v_TCR      (1,firstcell+1)
        outrcd( 3) = v_TCR      (numcomp_TCR ,firstcell+1)
        outrcd( 4) = v_TCR      (43,firstcell+1)
         z = 0.d0
          do i = firstcell, lastcell
           z = z - v_TCR(1,i)
          end do
        outrcd( 5) = z / dble(lastcell-firstcell+1) !  -av. cell somata 
         z = 0.d0
          do i = 1, numcomp_TCR      
           z = z + gAMPA_TCR      (i,firstcell+1)
          end do
        outrcd( 6) = z * 1000.d0 ! total AMPA cell 2 
         z = 0.d0
          do i = 1, numcomp_TCR      
           z = z + gNMDA_TCR      (i,firstcell+1)
          end do
        outrcd( 7) = z * 1000.d0 ! total NMDA cell 2 
         z = 0.d0
          do i = 1, numcomp_TCR      
           z = z + gGABA_A_TCR      (i,firstcell+1)
          end do
        outrcd( 8) = z * 1000.d0 ! total GABA-A, cell 2 
         z = 0.d0
          do i = 1, numcomp_TCR      
           z = z + gGABA_B_TCR      (i,firstcell+1)
          end do
        outrcd( 9) = z * 1000.d0 ! total GABA-B, cell 2 
        outrcd(10) = v_TCR      (1,firstcell+2)
        outrcd(11) = v_TCR      (1,firstcell+3)

          z = 0.d0
          do i = firstcell, lastcell
           if(v_TCR     (numcomp_TCR     ,i) .gt. 0.d0) z = z + 1.d0
          end do
        outrcd(12) = z   

        outrcd(13) = v_TCR (1,33)
        outrcd(14) = field_1mm_tot
        outrcd(15) = field_2mm_tot

         if (place(thisno).eq.1) then
      OPEN(23,FILE='spikewaveS96.TCR')
      WRITE (23,FMT='(15F10.4)') (OUTRCD(I),I=1,15)
         endif

c      else if (thisno.eq.13) then
       else IF (nodecell(thisno) .eq. 'nRT      ') THEN
c nRT       
c Determine which particular cells this node will be concerned with.
          i = place (thisno)
          firstcell = 1 + (i-1) * ncellspernode_nRT        
          lastcell = firstcell - 1 + ncellspernode_nRT       

        outrcd( 1) = time
        outrcd( 2) = v_nRT      (1,firstcell+1)
        outrcd( 3) = v_nRT      (numcomp_nRT ,firstcell+1)
        outrcd( 4) = v_nRT      (43,firstcell+1)
         z = 0.d0
          do i = firstcell, lastcell
           z = z - v_nRT(1,i)
          end do
        outrcd( 5) = z / dble(lastcell-firstcell+1) !  -av. cell somata 
         z = 0.d0
          do i = 1, numcomp_nRT       
           z = z + gAMPA_nRT      (i,firstcell+1)
          end do
        outrcd( 6) = z * 1000.d0 ! total AMPA cell 2 
         z = 0.d0
          do i = 1, numcomp_nRT         
           z = z + gNMDA_nRT      (i,firstcell+1)
          end do
        outrcd( 7) = z * 1000.d0 ! total NMDA cell 2 
         z = 0.d0
          do i = 1, numcomp_nRT        
           z = z + gGABA_A_nRT      (i,firstcell+1)
          end do
        outrcd( 8) = z * 1000.d0 ! total GABA-A, cell 2 
         z = 0.d0
          do i = 1, numcomp_nRT        
           z = z + gGABA_B_nRT      (i,firstcell+1)
          end do
        outrcd( 9) = z * 1000.d0 ! total GABA-B, cell 2 
        outrcd(10) = v_nRT      (1,firstcell+2)
        outrcd(11) = v_nRT      (1,firstcell+3)

          z = 0.d0
          do i = firstcell, lastcell
           if(v_nRT     (numcomp_nRT     ,i) .gt. 0.d0) z = z + 1.d0
          end do
        outrcd(12) = z   
        outrcd(13) = field_1mm_tot
        outrcd(14) = field_2mm_tot
         if (place(thisno).eq.1) then
c     OPEN(24,FILE='spikewaveS96.nRT')
c     WRITE (24,FMT='(14F10.4)') (OUTRCD(I),I=1,14)
         endif
       endif ! checking thisno

       endif ! mod(O, 50) = 0

        goto 1000
c END guts of main program

2000    CONTINUE
        time2 = gettime()
         if (thisno.eq.0) then
        write(6,3434) time2 - time1
         endif
3434    format(' elapsed time = ',f8.0,' secs')

        call mpi_finalize (info)
             END
c end main routine


c 11 Sept 2006, start with /interact/integrate_suppyrRSXP.f & add GABA-B
! 7 Nov. 2005: modify integrate_suppyrRSX.f to allow for Colbert-Pan axon.
!29 July 2005: modify groucho/integrate_suppyrRS.f, for a separate
! call for initialization, and to integrate only selected cells.
! Integration routine for suppyrRS cells
! Routine adapted from scortn in supergj.f
       SUBROUTINE INTEGRATE_suppyrRSXPB (O, time, numcell,     
     &    V, curr, initialize, firstcell, lastcell,
     & gAMPA, gNMDA, gGABA_A, gGABA_B,
     & Mg, 
     & gapcon  ,totaxgj   ,gjtable, dt,
     & totaxgj_mix, gjtable_mix, num_other, vax,
     &  chi,mnaf,mnap,
     &  hnaf,mkdr,mka,
     &  hka,mk2,hk2,
     &  mkm,mkc,mkahp,
     &  mcat,hcat,mcal,
     &  mar,field_1mm,field_2mm,rel_axonshift)
! num_other here = num suppyrFRB, vax = vax_suppyrFRB

       SAVE

       INTEGER, PARAMETER:: numcomp = 74
! numcomp here must be compatible with numcomp_suppyrRS in calling prog.
       INTEGER  numcell, num_other
       INTEGER initialize, firstcell, lastcell
       INTEGER J1, I, J, K, K1, K2, K3, L, L1, O
       REAL*8 c(numcomp), curr(numcomp,numcell)
       REAL*8  Z, Z1, Z2, Z3, Z4, DT, time
       integer totaxgj, gjtable(totaxgj,4)
       integer totaxgj_mix, gjtable_mix(totaxgj_mix,4)
       real*8 gapcon, gAMPA(numcomp,numcell),
     &        gNMDA(numcomp,numcell), gGABA_A(numcomp,numcell),
     &        gGABA_B(numcomp,numcell)
       real*8 Mg, V(numcomp,numcell)
!      real*8 vax (num_other), rel_axonshift
       real*8 vax (numcomp,num_other) ! "vax" now is voltages of another cell type,
! assumed to have same number of compartments as this cell type

c CINV is 1/C, i.e. inverse capacitance
       real*8 chi(numcomp,numcell),
     & mnaf(numcomp,numcell),mnap(numcomp,numcell),
     x hnaf(numcomp,numcell), mkdr(numcomp,numcell),
     x mka(numcomp,numcell),hka(numcomp,numcell),
     x mk2(numcomp,numcell), cinv(numcomp),
     x hk2(numcomp,numcell),mkm(numcomp,numcell),
     x mkc(numcomp,numcell),mkahp(numcomp,numcell),
     x mcat(numcomp,numcell),hcat(numcomp,numcell),
     x mcal(numcomp,numcell), betchi(numcomp),
     x mar(numcomp,numcell),jacob(numcomp,numcomp),
     x gam(0: numcomp,0: numcomp),gL(numcomp),gnaf(numcomp),
     x gnap(numcomp),gkdr(numcomp),gka(numcomp),
     x gk2(numcomp),gkm(numcomp),
     x gkc(numcomp),gkahp(numcomp),
     x gcat(numcomp),gcaL(numcomp),gar(numcomp),
     x cafor(numcomp)
       real*8
     X alpham_naf(0:640),betam_naf(0:640),dalpham_naf(0:640),
     X   dbetam_naf(0:640),
     X alphah_naf(0:640),betah_naf(0:640),dalphah_naf(0:640),
     X   dbetah_naf(0:640),
     X alpham_kdr(0:640),betam_kdr(0:640),dalpham_kdr(0:640),
     X   dbetam_kdr(0:640),
     X alpham_ka(0:640), betam_ka(0:640),dalpham_ka(0:640) ,
     X   dbetam_ka(0:640),
     X alphah_ka(0:640), betah_ka(0:640), dalphah_ka(0:640),
     X   dbetah_ka(0:640),
     X alpham_k2(0:640), betam_k2(0:640), dalpham_k2(0:640),
     X   dbetam_k2(0:640),
     X alphah_k2(0:640), betah_k2(0:640), dalphah_k2(0:640),
     X   dbetah_k2(0:640),
     X alpham_km(0:640), betam_km(0:640), dalpham_km(0:640),
     X   dbetam_km(0:640),
     X alpham_kc(0:640), betam_kc(0:640), dalpham_kc(0:640),
     X   dbetam_kc(0:640),
     X alpham_cat(0:640),betam_cat(0:640),dalpham_cat(0:640),
     X   dbetam_cat(0:640),
     X alphah_cat(0:640),betah_cat(0:640),dalphah_cat(0:640),
     X   dbetah_cat(0:640),
     X alpham_caL(0:640),betam_caL(0:640),dalpham_caL(0:640),
     X   dbetam_caL(0:640),
     X alpham_ar(0:640), betam_ar(0:640), dalpham_ar(0:640),
     X   dbetam_ar(0:640)
       real*8 vL(numcomp),vk(numcomp),vna,var,vca,vgaba_a
       real*8 depth(12), membcurr(12), field_1mm, field_2mm
       integer level(numcomp)

        INTEGER NEIGH(numcomp,10), NNUM(numcomp)
        INTEGER igap1, igap2
c the f's are the functions giving 1st derivatives for evolution of
c the differential equations for the voltages (v), calcium (chi), and
c other state variables.
       real*8 fv(numcomp), fchi(numcomp),
     x fmnaf(numcomp),fhnaf(numcomp),fmkdr(numcomp),
     x fmka(numcomp),fhka(numcomp),fmk2(numcomp),
     x fhk2(numcomp),fmnap(numcomp),
     x fmkm(numcomp),fmkc(numcomp),fmkahp(numcomp),
     x fmcat(numcomp),fhcat(numcomp),fmcal(numcomp),
     x fmar(numcomp)

c below are for calculating the partial derivatives
       real*8 dfv_dv(numcomp,numcomp), dfv_dchi(numcomp),
     x  dfv_dmnaf(numcomp),  dfv_dmnap(numcomp),
     x  dfv_dhnaf(numcomp),dfv_dmkdr(numcomp),
     x  dfv_dmka(numcomp),dfv_dhka(numcomp),
     x  dfv_dmk2(numcomp),dfv_dhk2(numcomp),
     x  dfv_dmkm(numcomp),dfv_dmkc(numcomp),
     x  dfv_dmkahp(numcomp),dfv_dmcat(numcomp),
     x  dfv_dhcat(numcomp),dfv_dmcal(numcomp),
     x  dfv_dmar(numcomp)

        real*8 dfchi_dv(numcomp), dfchi_dchi(numcomp),
     x dfmnaf_dmnaf(numcomp), dfmnaf_dv(numcomp),
     x dfhnaf_dhnaf(numcomp),
     x dfmnap_dmnap(numcomp), dfmnap_dv(numcomp),
     x dfhnaf_dv(numcomp),dfmkdr_dmkdr(numcomp),
     x dfmkdr_dv(numcomp),
     x dfmka_dmka(numcomp),dfmka_dv(numcomp),
     x dfhka_dhka(numcomp),dfhka_dv(numcomp),
     x dfmk2_dmk2(numcomp),dfmk2_dv(numcomp),
     x dfhk2_dhk2(numcomp),dfhk2_dv(numcomp),
     x dfmkm_dmkm(numcomp),dfmkm_dv(numcomp),
     x dfmkc_dmkc(numcomp),dfmkc_dv(numcomp),
     x dfmcat_dmcat(numcomp),dfmcat_dv(numcomp),dfhcat_dhcat(numcomp),
     x dfhcat_dv(numcomp),dfmcal_dmcal(numcomp),dfmcal_dv(numcomp),
     x dfmar_dmar(numcomp),dfmar_dv(numcomp),dfmkahp_dchi(numcomp),
     x dfmkahp_dmkahp(numcomp), dt2

       REAL*8 OPEN(numcomp),gamma(numcomp),gamma_prime(numcomp)
c gamma is function of chi used in calculating KC conductance
       REAL*8 alpham_ahp(numcomp), alpham_ahp_prime(numcomp)
       REAL*8 gna_tot(numcomp),gk_tot(numcomp),gca_tot(numcomp)
       REAL*8 gca_high(numcomp), gar_tot(numcomp)
c this will be gCa conductance corresponding to high-thresh channels

       real*8 persistentNa_shift, fastNa_shift_SD,
     x   fastNa_shift_axon

       REAL*8 A, BB1, BB2  ! params. for FNMDA.f


c          if (O.eq.1) then
           if (initialize.eq.0) then
c do initialization

c Program fnmda assumes A, BB1, BB2 defined in calling program
c as follows:
         A = DEXP(-2.847d0)
         BB1 = DEXP(-.693d0)
         BB2 = DEXP(-3.101d0)

c       goto 4000
       CALL   SCORT_SETUP_suppyrRS
     X   (alpham_naf, betam_naf, dalpham_naf, dbetam_naf,
     X    alphah_naf, betah_naf, dalphah_naf, dbetah_naf,
     X    alpham_kdr, betam_kdr, dalpham_kdr, dbetam_kdr,
     X    alpham_ka , betam_ka , dalpham_ka , dbetam_ka ,
     X    alphah_ka , betah_ka , dalphah_ka , dbetah_ka ,
     X    alpham_k2 , betam_k2 , dalpham_k2 , dbetam_k2 ,
     X    alphah_k2 , betah_k2 , dalphah_k2 , dbetah_k2 ,
     X    alpham_km , betam_km , dalpham_km , dbetam_km ,
     X    alpham_kc , betam_kc , dalpham_kc , dbetam_kc ,
     X    alpham_cat, betam_cat, dalpham_cat, dbetam_cat,
     X    alphah_cat, betah_cat, dalphah_cat, dbetah_cat,
     X    alpham_caL, betam_caL, dalpham_caL, dbetam_caL,
     X    alpham_ar , betam_ar , dalpham_ar , dbetam_ar)

        CALL SCORTMAJ_suppyrRS
     X             (GL,GAM,GKDR,GKA,GKC,GKAHP,GK2,GKM,
     X              GCAT,GCAL,GNAF,GNAP,GAR,
     X    CAFOR,JACOB,C,BETCHI,NEIGH,NNUM,depth,level)

          do i = 1, numcomp
             cinv(i) = 1.d0 / c(i)
          end do
4000      CONTINUE

           do i = 1, numcomp
          vL(i) = -70.d0
          vK(i) = -95.d0
           end do

        VNA = 50.d0
        VCA = 125.d0
        VAR = -43.d0
        VAR = -35.d0
c -43 mV from Huguenard & McCormick
        VGABA_A = -81.d0
c       write(6,901) VNa, VCa, VK(1), O
901     format('VNa =',f6.2,' VCa =',f6.2,' VK =',f6.2,
     &   ' O = ',i3)

c ? initialize membrane state variables?
         do L = 1, numcell  
         do i = 1, numcomp
        v(i,L) = VL(i)
	chi(i,L) = 0.d0
	mnaf(i,L) = 0.d0
	mkdr(i,L) = 0.d0
	mk2(i,L) = 0.d0
	mkm(i,L) = 0.d0
	mkc(i,L) = 0.d0
	mkahp(i,L) = 0.d0
	mcat(i,L) = 0.d0
	mcal(i,L) = 0.d0
         end do
         end do

          do L = 1, numcell
        k1 = idnint (4.d0 * (v(1,L) + 120.d0))

            do i = 1, numcomp
      hnaf(i,L) = alphah_naf(k1)/(alphah_naf(k1)
     &       +betah_naf(k1))
      hka(i,L) = alphah_ka(k1)/(alphah_ka(k1)
     &                               +betah_ka(k1))
      hk2(i,L) = alphah_k2(k1)/(alphah_k2(k1)
     &                                +betah_k2(k1))
      hcat(i,L)=alphah_cat(k1)/(alphah_cat(k1)
     &                                +betah_cat(k1))
c     mar=alpham_ar(k1)/(alpham_ar(k1)+betam_ar(k1))
      mar(i,L) = .25d0
             end do
           end do


             do i = 1, numcomp
	    open(i) = 0.d0
            gkm(i) = 2.d0 * gkm(i)
             end do

         do i = 1, 68
c          gnaf(i) = 0.8d0 * 1.25d0 * gnaf(i) ! factor of 0.8 added 19 Nov. 2005
c          gnaf(i) = 0.9d0 * 1.25d0 * gnaf(i) ! Back to 0.9, 29 Nov. 2005
           gnaf(i) = 0.6d0 * 1.25d0 * gnaf(i) ! 
! NOTE THAT THERE IS QUESTION OF HOW TO COMPARE BEHAVIOR OF PYRAMID IN NETWORK WITH
! SIMULATIONS OF SINGLE CELL.  IN FORMER CASE, THERE IS LARGE AXONAL SHUNT THROUGH
! gj(s), NOT PRESENT IN SINGLE CELL MODEL.  THEREFORE, HIGHER AXONAL gNa MIGHT BE
! NECESSARY FOR SPIKE PROPAGATION.
c          gnaf(i) = 0.9d0 * 1.25d0 * gnaf(i) ! factor of 0.9 added 20 Nov. 2005
           gkdr(i) = 1.25d0 * gkdr(i)
         end do
 
c Perhaps reduce fast gNa on IS
          gnaf(69) = 1.00d0 * gnaf(69)
c         gnaf(69) = 0.25d0 * gnaf(69)
          gnaf(70) = 1.00d0 * gnaf(70)
c         gnaf(70) = 0.25d0 * gnaf(70)

c Perhaps reduce coupling between soma and IS
c         gam(1,69) = 0.15d0 * gam(1,69)
c         gam(69,1) = 0.15d0 * gam(69,1)

c Determine which cells are FRB and which RS.
c           if (L.le.(nL2-nFRB)) then
               z1 = 0.0d0
c              z1 = 0.2d0
c              z2 = 2.2d0
               z2 = 1.2d0 ! value 1.2 tried Feb. 21, 2013
               z3 = 1.0d0
c              z3 = 0.0d0 ! Note reduction from 0.4, to prevent
c slow hyperpolarization that seems to mess up gamma.
c              z4 = 1.0d0
               z4 = 0.3d0
c RS cell
c           else
c              z1 = 1.50d0
c              z2 = 0.6d0
c              z3 = 1.d0
c              z4 = 1.d0
c FRB cell
c           endif
             do i = 1, numcomp
              gnap(i) = z1 * gnap(i)
              gkc (i) = z2 * gkc (i)
              gkahp(i) = z3 * gkahp(i)
              gkm (i) = z4 * gkm (i)
             end do

              goto 6000

          endif
c End initialization

          do i = 1, 12
           membcurr(i) = 0.d0
          end do

c                  goto 2001


c             do L = 1, numcell
              do L = firstcell, lastcell

	  do i = 1, numcomp
	  do j = 1, nnum(i)
	   if (neigh(i,j).gt.numcomp) then
          write(6,433) i, j, L
433       format(' ls ',3x,3i5)
           endif
	end do
	end do

       DO I = 1, numcomp
          FV(I) = -GL(I) * (V(I,L) - VL(i)) * cinv(i)
          DO J = 1, NNUM(I)
             K = NEIGH(I,J)
302     FV(I) = FV(I) + GAM(I,K) * (V(K,L) - V(I,L)) * cinv(i)
           END DO
       END DO
301    CONTINUE


       CALL FNMDA (V, OPEN, numcell, numcomp, MG, L,
     &                 A, BB1, BB2)

      DO I = 1, numcomp
       FV(I) = FV(I) + ( CURR(I,L)
     X   - (gampa(I,L) + open(i) * gnmda(I,L))*V(I,L)
     X   - ggaba_a(I,L)*(V(I,L)-Vgaba_a) 
     X   - ggaba_b(I,L)*(V(I,L)-VK(i)  ) ) * cinv(i)
c above assumes equil. potential for AMPA & NMDA = 0 mV
      END DO
421      continue

       do m = 1, totaxgj
        if (gjtable(m,1).eq.L) then
         L1 = gjtable(m,3)
         igap1 = gjtable(m,2)
         igap2 = gjtable(m,4)
 	fv(igap1) = fv(igap1) + gapcon *
     &   (v(igap2,L1) - v(igap1,L)) * cinv(igap1)
        else if (gjtable(m,3).eq.L) then
         L1 = gjtable(m,1)
         igap1 = gjtable(m,4)
         igap2 = gjtable(m,2)
 	fv(igap1) = fv(igap1) + gapcon *
     &   (v(igap2,L1) - v(igap1,L)) * cinv(igap1)
        endif
       end do ! do m

       do m = 1, totaxgj_mix
        if (gjtable_mix(m,1).eq.L) then
         L1 = gjtable_mix(m,3)
         igap1 = gjtable_mix(m,2)
 	fv(igap1) = fv(igap1) + gapcon *
c    &   (vax(L1) - v(igap1,L)) * cinv(igap1)
     &   (vax(igap1,L1) - v(igap1,L)) * cinv(igap1)
c Note that compartments assumed to match
        endif
       end do ! do m

c      do i = 1, ngap(L) ! OBSOLETE CODE FROM SUPERGJ.F
c      L1 = list_gap(L,i)
c	fv(axsite) = fv(axsite) + gapcon *
c    &   (vaxgap_global(L1) - v(axsite,L)) * cinv(axsite)
c      end do  ! OBSOLETE CODE FROM SUPERGJ.F

       do i = 1, numcomp
        gamma(i) = dmin1 (1.d0, .004d0 * chi(i,L))
        if (chi(i,L).le.250.d0) then
          gamma_prime(i) = .004d0
        else
          gamma_prime(i) = 0.d0
        endif
c         endif
       end do

      DO I = 1, numcomp
       gna_tot(i) = gnaf(i) * (mnaf(i,L)**3) * hnaf(i,L) +
     x     gnap(i) * mnap(i,L)
       gk_tot(i) = gkdr(i) * (mkdr(i,L)**4) +
     x             gka(i)  * (mka(i,L)**4) * hka(i,L) +
     x             gk2(i)  * mk2(i,L) * hk2(i,L) +
     x             gkm(i)  * mkm(i,L) +
     x             gkc(i)  * mkc(i,L) * gamma(i) +
     x             gkahp(i)* mkahp(i,L)
       gca_tot(i) = gcat(i) * (mcat(i,L)**2) * hcat(i,L) +
     x              gcaL(i) * (mcaL(i,L)**2)
       gca_high(i) =
     x              gcaL(i) * (mcaL(i,L)**2)
       gar_tot(i) = gar(i) * mar(i,L)


       FV(I) = FV(I) - ( gna_tot(i) * (v(i,L) - vna)
     X  + gk_tot(i) * (v(i,L) - vK(i))
     X  + gca_tot(i) * (v(i,L) - vCa)
     X  + gar_tot(i) * (v(i,L) - var) ) * cinv(i)
c        endif
       END DO
88           continue

         do i = 1, numcomp
         do j = 1, numcomp
          if (i.ne.j) then
            dfv_dv(i,j) = jacob(i,j)
          else
            dfv_dv(i,j) = jacob(i,i) - cinv(i) *
     X  (gna_tot(i) + gk_tot(i) + gca_tot(i) + gar_tot(i)
     X   + ggaba_a(i,L) + ggaba_b(i,L) + gampa(i,L)
     X   + open(i) * gnmda(I,L) )
          endif
         end do
         end do

           do i = 1, numcomp
        dfv_dchi(i)  = - cinv(i) * gkc(i) * mkc(i,L) *
     x                     gamma_prime(i) * (v(i,L)-vK(i))
        dfv_dmnaf(i) = -3.d0 * cinv(i) * (mnaf(i,L)**2) *
     X    (gnaf(i) * hnaf(i,L)          ) * (v(i,L) - vna)
        dfv_dmnap(i) = - cinv(i) *
     X    (               gnap(i)) * (v(i,L) - vna)
        dfv_dhnaf(i) = - cinv(i) * gnaf(i) * (mnaf(i,L)**3) *
     X                    (v(i,L) - vna)
        dfv_dmkdr(i) = -4.d0 * cinv(i) * gkdr(i) * (mkdr(i,L)**3)
     X                   * (v(i,L) - vK(i))
        dfv_dmka(i)  = -4.d0 * cinv(i) * gka(i) * (mka(i,L)**3) *
     X                   hka(i,L) * (v(i,L) - vK(i))
        dfv_dhka(i)  = - cinv(i) * gka(i) * (mka(i,L)**4) *
     X                    (v(i,L) - vK(i))
      dfv_dmk2(i) = - cinv(i) * gk2(i) * hk2(i,L) * (v(i,L)-vK(i))
      dfv_dhk2(i) = - cinv(i) * gk2(i) * mk2(i,L) * (v(i,L)-vK(i))
      dfv_dmkm(i) = - cinv(i) * gkm(i) * (v(i,L) - vK(i))
      dfv_dmkc(i) = - cinv(i)*gkc(i) * gamma(i) * (v(i,L)-vK(i))
        dfv_dmkahp(i)= - cinv(i) * gkahp(i) * (v(i,L) - vK(i))
        dfv_dmcat(i)  = -2.d0 * cinv(i) * gcat(i) * mcat(i,L) *
     X                    hcat(i,L) * (v(i,L) - vCa)
        dfv_dhcat(i) = - cinv(i) * gcat(i) * (mcat(i,L)**2) *
     X                  (v(i,L) - vCa)
        dfv_dmcal(i) = -2.d0 * cinv(i) * gcal(i) * mcal(i,L) *
     X                      (v(i,L) - vCa)
        dfv_dmar(i) = - cinv(i) * gar(i) * (v(i,L) - var)
            end do

         do i = 1, numcomp
          fchi(i) = - cafor(i) * gca_high(i) * (v(i,L) - vca)
     x       - betchi(i) * chi(i,L)
          dfchi_dv(i) = - cafor(i) * gca_high(i)
          dfchi_dchi(i) = - betchi(i)
         end do

       do i = 1, numcomp
c Note possible increase in rate at which AHP current develops
c       alpham_ahp(i) = dmin1(0.2d-4 * chi(i,L),0.01d0)
        alpham_ahp(i) = dmin1(1.0d-4 * chi(i,L),0.01d0)
        if (chi(i,L).le.500.d0) then
c         alpham_ahp_prime(i) = 0.2d-4
          alpham_ahp_prime(i) = 1.0d-4
        else
          alpham_ahp_prime(i) = 0.d0
        endif
       end do

       do i = 1, numcomp
        fmkahp(i) = alpham_ahp(i) * (1.d0 - mkahp(i,L))
c    x                  -.001d0 * mkahp(i,L)
     x                  -.010d0 * mkahp(i,L)
c       dfmkahp_dmkahp(i) = - alpham_ahp(i) - .001d0
        dfmkahp_dmkahp(i) = - alpham_ahp(i) - .010d0
        dfmkahp_dchi(i) = alpham_ahp_prime(i) *
     x                     (1.d0 - mkahp(i,L))
       end do

          do i = 1, numcomp

       K1 = IDNINT ( 4.d0 * (V(I,L) + 120.d0) )
       IF (K1.GT.640) K1 = 640
       IF (K1.LT.  0) K1 =   0

c      persistentNa_shift =  0.d0
c      persistentNa_shift =  8.d0
       persistentNa_shift = 10.d0
       K2 = IDNINT ( 4.d0 * (V(I,L)+persistentNa_shift+ 120.d0) )
       IF (K2.GT.640) K2 = 640
       IF (K2.LT.  0) K2 =   0

c            fastNa_shift = -2.0d0
c            fastNa_shift = -2.5d0
             fastNa_shift_SD = -3.5d0
             fastNa_shift_axon = fastNa_shift_SD + rel_axonshift 
       K0 = IDNINT ( 4.d0 * (V(I,L)+  fastNa_shift_SD+ 120.d0) )
       IF (K0.GT.640) K0 = 640
       IF (K0.LT.  0) K0 =   0
       K3 = IDNINT ( 4.d0 * (V(I,L)+  fastNa_shift_axon+ 120.d0) )
       IF (K3.GT.640) K3 = 640
       IF (K3.LT.  0) K3 =   0

         if (i.le.68) then   ! FOR SD
        fmnaf(i) = alpham_naf(k0) * (1.d0 - mnaf(i,L)) -
     X              betam_naf(k0) * mnaf(i,L)
        fhnaf(i) = alphah_naf(k0) * (1.d0 - hnaf(i,L)) -
     X              betah_naf(k0) * hnaf(i,L)
         else  ! for axon
        fmnaf(i) = alpham_naf(k3) * (1.d0 - mnaf(i,L)) -
     X              betam_naf(k3) * mnaf(i,L)
        fhnaf(i) = alphah_naf(k3) * (1.d0 - hnaf(i,L)) -
     X              betah_naf(k3) * hnaf(i,L)
         endif
        fmnap(i) = alpham_naf(k2) * (1.d0 - mnap(i,L)) -
     X              betam_naf(k2) * mnap(i,L)
        fmkdr(i) = alpham_kdr(k1) * (1.d0 - mkdr(i,L)) -
     X              betam_kdr(k1) * mkdr(i,L)
        fmka(i)  = alpham_ka (k1) * (1.d0 - mka(i,L)) -
     X              betam_ka (k1) * mka(i,L)
        fhka(i)  = alphah_ka (k1) * (1.d0 - hka(i,L)) -
     X              betah_ka (k1) * hka(i,L)
        fmk2(i)  = alpham_k2 (k1) * (1.d0 - mk2(i,L)) -
     X              betam_k2 (k1) * mk2(i,L)
        fhk2(i)  = alphah_k2 (k1) * (1.d0 - hk2(i,L)) -
     X              betah_k2 (k1) * hk2(i,L)
        fmkm(i)  = alpham_km (k1) * (1.d0 - mkm(i,L)) -
     X              betam_km (k1) * mkm(i,L)
        fmkc(i)  = alpham_kc (k1) * (1.d0 - mkc(i,L)) -
     X              betam_kc (k1) * mkc(i,L)
        fmcat(i) = alpham_cat(k1) * (1.d0 - mcat(i,L)) -
     X              betam_cat(k1) * mcat(i,L)
        fhcat(i) = alphah_cat(k1) * (1.d0 - hcat(i,L)) -
     X              betah_cat(k1) * hcat(i,L)
        fmcaL(i) = alpham_caL(k1) * (1.d0 - mcaL(i,L)) -
     X              betam_caL(k1) * mcaL(i,L)
        fmar(i)  = alpham_ar (k1) * (1.d0 - mar(i,L)) -
     X              betam_ar (k1) * mar(i,L)

       dfmnaf_dv(i) = dalpham_naf(k0) * (1.d0 - mnaf(i,L)) -
     X                  dbetam_naf(k0) * mnaf(i,L)
       dfmnap_dv(i) = dalpham_naf(k2) * (1.d0 - mnap(i,L)) -
     X                  dbetam_naf(k2) * mnap(i,L)
       dfhnaf_dv(i) = dalphah_naf(k1) * (1.d0 - hnaf(i,L)) -
     X                  dbetah_naf(k1) * hnaf(i,L)
       dfmkdr_dv(i) = dalpham_kdr(k1) * (1.d0 - mkdr(i,L)) -
     X                  dbetam_kdr(k1) * mkdr(i,L)
       dfmka_dv(i)  = dalpham_ka(k1) * (1.d0 - mka(i,L)) -
     X                  dbetam_ka(k1) * mka(i,L)
       dfhka_dv(i)  = dalphah_ka(k1) * (1.d0 - hka(i,L)) -
     X                  dbetah_ka(k1) * hka(i,L)
       dfmk2_dv(i)  = dalpham_k2(k1) * (1.d0 - mk2(i,L)) -
     X                  dbetam_k2(k1) * mk2(i,L)
       dfhk2_dv(i)  = dalphah_k2(k1) * (1.d0 - hk2(i,L)) -
     X                  dbetah_k2(k1) * hk2(i,L)
       dfmkm_dv(i)  = dalpham_km(k1) * (1.d0 - mkm(i,L)) -
     X                  dbetam_km(k1) * mkm(i,L)
       dfmkc_dv(i)  = dalpham_kc(k1) * (1.d0 - mkc(i,L)) -
     X                  dbetam_kc(k1) * mkc(i,L)
       dfmcat_dv(i) = dalpham_cat(k1) * (1.d0 - mcat(i,L)) -
     X                  dbetam_cat(k1) * mcat(i,L)
       dfhcat_dv(i) = dalphah_cat(k1) * (1.d0 - hcat(i,L)) -
     X                  dbetah_cat(k1) * hcat(i,L)
       dfmcaL_dv(i) = dalpham_caL(k1) * (1.d0 - mcaL(i,L)) -
     X                  dbetam_caL(k1) * mcaL(i,L)
       dfmar_dv(i)  = dalpham_ar(k1) * (1.d0 - mar(i,L)) -
     X                  dbetam_ar(k1) * mar(i,L)

       dfmnaf_dmnaf(i) =  - alpham_naf(k0) - betam_naf(k0)
       dfmnap_dmnap(i) =  - alpham_naf(k2) - betam_naf(k2)
       dfhnaf_dhnaf(i) =  - alphah_naf(k1) - betah_naf(k1)
       dfmkdr_dmkdr(i) =  - alpham_kdr(k1) - betam_kdr(k1)
       dfmka_dmka(i)  =   - alpham_ka (k1) - betam_ka (k1)
       dfhka_dhka(i)  =   - alphah_ka (k1) - betah_ka (k1)
       dfmk2_dmk2(i)  =   - alpham_k2 (k1) - betam_k2 (k1)
       dfhk2_dhk2(i)  =   - alphah_k2 (k1) - betah_k2 (k1)
       dfmkm_dmkm(i)  =   - alpham_km (k1) - betam_km (k1)
       dfmkc_dmkc(i)  =   - alpham_kc (k1) - betam_kc (k1)
       dfmcat_dmcat(i) =  - alpham_cat(k1) - betam_cat(k1)
       dfhcat_dhcat(i) =  - alphah_cat(k1) - betah_cat(k1)
       dfmcaL_dmcaL(i) =  - alpham_caL(k1) - betam_caL(k1)
       dfmar_dmar(i)  =   - alpham_ar (k1) - betam_ar (k1)

          end do

       dt2 = 0.5d0 * dt * dt

        do i = 1, numcomp
          v(i,L) = v(i,L) + dt * fv(i)
           do j = 1, numcomp
        v(i,L) = v(i,L) + dt2 * dfv_dv(i,j) * fv(j)
           end do
        v(i,L) = v(i,L) + dt2 * ( dfv_dchi(i) * fchi(i)
     X          + dfv_dmnaf(i) * fmnaf(i)
     X          + dfv_dmnap(i) * fmnap(i)
     X          + dfv_dhnaf(i) * fhnaf(i)
     X          + dfv_dmkdr(i) * fmkdr(i)
     X          + dfv_dmka(i)  * fmka(i)
     X          + dfv_dhka(i)  * fhka(i)
     X          + dfv_dmk2(i)  * fmk2(i)
     X          + dfv_dhk2(i)  * fhk2(i)
     X          + dfv_dmkm(i)  * fmkm(i)
     X          + dfv_dmkc(i)  * fmkc(i)
     X          + dfv_dmkahp(i)* fmkahp(i)
     X          + dfv_dmcat(i)  * fmcat(i)
     X          + dfv_dhcat(i) * fhcat(i)
     X          + dfv_dmcaL(i) * fmcaL(i)
     X          + dfv_dmar(i)  * fmar(i) )

        chi(i,L) = chi(i,L) + dt * fchi(i) + dt2 *
     X   (dfchi_dchi(i) * fchi(i) + dfchi_dv(i) * fv(i))
        mnaf(i,L) = mnaf(i,L) + dt * fmnaf(i) + dt2 *
     X   (dfmnaf_dmnaf(i) * fmnaf(i) + dfmnaf_dv(i)*fv(i))
        mnap(i,L) = mnap(i,L) + dt * fmnap(i) + dt2 *
     X   (dfmnap_dmnap(i) * fmnap(i) + dfmnap_dv(i)*fv(i))
        hnaf(i,L) = hnaf(i,L) + dt * fhnaf(i) + dt2 *
     X   (dfhnaf_dhnaf(i) * fhnaf(i) + dfhnaf_dv(i)*fv(i))
        mkdr(i,L) = mkdr(i,L) + dt * fmkdr(i) + dt2 *
     X   (dfmkdr_dmkdr(i) * fmkdr(i) + dfmkdr_dv(i)*fv(i))
        mka(i,L) =  mka(i,L) + dt * fmka(i) + dt2 *
     X   (dfmka_dmka(i) * fmka(i) + dfmka_dv(i) * fv(i))
        hka(i,L) =  hka(i,L) + dt * fhka(i) + dt2 *
     X   (dfhka_dhka(i) * fhka(i) + dfhka_dv(i) * fv(i))
        mk2(i,L) =  mk2(i,L) + dt * fmk2(i) + dt2 *
     X   (dfmk2_dmk2(i) * fmk2(i) + dfmk2_dv(i) * fv(i))
        hk2(i,L) =  hk2(i,L) + dt * fhk2(i) + dt2 *
     X   (dfhk2_dhk2(i) * fhk2(i) + dfhk2_dv(i) * fv(i))
        mkm(i,L) =  mkm(i,L) + dt * fmkm(i) + dt2 *
     X   (dfmkm_dmkm(i) * fmkm(i) + dfmkm_dv(i) * fv(i))
        mkc(i,L) =  mkc(i,L) + dt * fmkc(i) + dt2 *
     X   (dfmkc_dmkc(i) * fmkc(i) + dfmkc_dv(i) * fv(i))
        mkahp(i,L) = mkahp(i,L) + dt * fmkahp(i) + dt2 *
     X (dfmkahp_dmkahp(i)*fmkahp(i) + dfmkahp_dchi(i)*fchi(i))
        mcat(i,L) =  mcat(i,L) + dt * fmcat(i) + dt2 *
     X   (dfmcat_dmcat(i) * fmcat(i) + dfmcat_dv(i) * fv(i))
        hcat(i,L) =  hcat(i,L) + dt * fhcat(i) + dt2 *
     X   (dfhcat_dhcat(i) * fhcat(i) + dfhcat_dv(i) * fv(i))
        mcaL(i,L) =  mcaL(i,L) + dt * fmcaL(i) + dt2 *
     X   (dfmcaL_dmcaL(i) * fmcaL(i) + dfmcaL_dv(i) * fv(i))
        mar(i,L) =   mar(i,L) + dt * fmar(i) + dt2 *
     X   (dfmar_dmar(i) * fmar(i) + dfmar_dv(i) * fv(i))
c            endif
         end do

! Add membrane currents into membcurr for appropriate compartments
          do i = 1, 9
           j = level(i)
           membcurr(j) = membcurr(j) + fv(i) * c(i)
          end do
          do i = 14, 21
           j = level(i)
           membcurr(j) = membcurr(j) + fv(i) * c(i)
          end do
          do i = 26, 33
           j = level(i)
           membcurr(j) = membcurr(j) + fv(i) * c(i)
          end do
          do i = 39, 68
           j = level(i)
           membcurr(j) = membcurr(j) + fv(i) * c(i)
          end do

            end do
c Finish loop L = 1 to numcell

         field_1mm = 0.d0
         field_2mm = 0.d0

         do i = 1, 12
          field_1mm = field_1mm + membcurr(i) / dabs(1000.d0 - depth(i))
          field_2mm = field_2mm + membcurr(i) / dabs(2000.d0 - depth(i))
         end do

2001          CONTINUE

6000    END



C  SETS UP TABLES FOR RATE FUNCTIONS
       SUBROUTINE SCORT_SETUP_suppyrRS
     X   (alpham_naf, betam_naf, dalpham_naf, dbetam_naf,
     X    alphah_naf, betah_naf, dalphah_naf, dbetah_naf,
     X    alpham_kdr, betam_kdr, dalpham_kdr, dbetam_kdr,
     X    alpham_ka , betam_ka , dalpham_ka , dbetam_ka ,
     X    alphah_ka , betah_ka , dalphah_ka , dbetah_ka ,
     X    alpham_k2 , betam_k2 , dalpham_k2 , dbetam_k2 ,
     X    alphah_k2 , betah_k2 , dalphah_k2 , dbetah_k2 ,
     X    alpham_km , betam_km , dalpham_km , dbetam_km ,
     X    alpham_kc , betam_kc , dalpham_kc , dbetam_kc ,
     X    alpham_cat, betam_cat, dalpham_cat, dbetam_cat,
     X    alphah_cat, betah_cat, dalphah_cat, dbetah_cat,
     X    alpham_caL, betam_caL, dalpham_caL, dbetam_caL,
     X    alpham_ar , betam_ar , dalpham_ar , dbetam_ar)
      INTEGER I,J,K
      real*8 minf, hinf, taum, tauh, V, Z, shift_hnaf,
     X  shift_mkdr,
     X alpham_naf(0:640),betam_naf(0:640),dalpham_naf(0:640),
     X   dbetam_naf(0:640),
     X alphah_naf(0:640),betah_naf(0:640),dalphah_naf(0:640),
     X   dbetah_naf(0:640),
     X alpham_kdr(0:640),betam_kdr(0:640),dalpham_kdr(0:640),
     X   dbetam_kdr(0:640),
     X alpham_ka(0:640), betam_ka(0:640),dalpham_ka(0:640) ,
     X   dbetam_ka(0:640),
     X alphah_ka(0:640), betah_ka(0:640), dalphah_ka(0:640),
     X   dbetah_ka(0:640),
     X alpham_k2(0:640), betam_k2(0:640), dalpham_k2(0:640),
     X   dbetam_k2(0:640),
     X alphah_k2(0:640), betah_k2(0:640), dalphah_k2(0:640),
     X   dbetah_k2(0:640),
     X alpham_km(0:640), betam_km(0:640), dalpham_km(0:640),
     X   dbetam_km(0:640),
     X alpham_kc(0:640), betam_kc(0:640), dalpham_kc(0:640),
     X   dbetam_kc(0:640),
     X alpham_cat(0:640),betam_cat(0:640),dalpham_cat(0:640),
     X   dbetam_cat(0:640),
     X alphah_cat(0:640),betah_cat(0:640),dalphah_cat(0:640),
     X   dbetah_cat(0:640),
     X alpham_caL(0:640),betam_caL(0:640),dalpham_caL(0:640),
     X   dbetam_caL(0:640),
     X alpham_ar(0:640), betam_ar(0:640), dalpham_ar(0:640),
     X   dbetam_ar(0:640)
C FOR VOLTAGE, RANGE IS -120 TO +40 MV (absol.), 0.25 MV RESOLUTION


       DO 1, I = 0, 640
          V = dble(I)
          V = (V / 4.d0) - 120.d0

c gNa
           minf = 1.d0/(1.d0 + dexp((-V-38.d0)/10.d0))
           if (v.le.-30.d0) then
            taum = .025d0 + .14d0*dexp((v+30.d0)/10.d0)
           else
            taum = .02d0 + .145d0*dexp((-v-30.d0)/10.d0)
           endif
c from principal c. data, Martina & Jonas 1997, tau x 0.5
c Note that minf about the same for interneuron & princ. cell.
           alpham_naf(i) = minf / taum
           betam_naf(i) = 1.d0/taum - alpham_naf(i)

            shift_hnaf =  0.d0
        hinf = 1.d0/(1.d0 +
     x     dexp((v + shift_hnaf + 62.9d0)/10.7d0))
        tauh = 0.15d0 + 1.15d0/(1.d0+dexp((v+37.d0)/15.d0))
c from princ. cell data, Martina & Jonas 1997, tau x 0.5
            alphah_naf(i) = hinf / tauh
            betah_naf(i) = 1.d0/tauh - alphah_naf(i)

          shift_mkdr = 0.d0
c delayed rectifier, non-inactivating
       minf = 1.d0/(1.d0+dexp((-v-shift_mkdr-29.5d0)/10.0d0))
            if (v.le.-10.d0) then
             taum = .25d0 + 4.35d0*dexp((v+10.d0)/10.d0)
            else
             taum = .25d0 + 4.35d0*dexp((-v-10.d0)/10.d0)
            endif
              alpham_kdr(i) = minf / taum
              betam_kdr(i) = 1.d0 /taum - alpham_kdr(i)
c from Martina, Schultz et al., 1998. See espec. Table 1.

c A current: Huguenard & McCormick 1992, J Neurophysiol (TCR)
            minf = 1.d0/(1.d0 + dexp((-v-60.d0)/8.5d0))
            hinf = 1.d0/(1.d0 + dexp((v+78.d0)/6.d0))
        taum = .185d0 + .5d0/(dexp((v+35.8d0)/19.7d0) +
     x                            dexp((-v-79.7d0)/12.7d0))
        if (v.le.-63.d0) then
         tauh = .5d0/(dexp((v+46.d0)/5.d0) +
     x                  dexp((-v-238.d0)/37.5d0))
        else
         tauh = 9.5d0
        endif
           alpham_ka(i) = minf/taum
           betam_ka(i) = 1.d0 / taum - alpham_ka(i)
           alphah_ka(i) = hinf / tauh
           betah_ka(i) = 1.d0 / tauh - alphah_ka(i)

c h-current (anomalous rectifier), Huguenard & McCormick, 1992
           minf = 1.d0/(1.d0 + dexp((v+75.d0)/5.5d0))
           taum = 1.d0/(dexp(-14.6d0 -0.086d0*v) +
     x                   dexp(-1.87 + 0.07d0*v))
           alpham_ar(i) = minf / taum
           betam_ar(i) = 1.d0 / taum - alpham_ar(i)

c K2 K-current, McCormick & Huguenard
             minf = 1.d0/(1.d0 + dexp((-v-10.d0)/17.d0))
             hinf = 1.d0/(1.d0 + dexp((v+58.d0)/10.6d0))
            taum = 4.95d0 + 0.5d0/(dexp((v-81.d0)/25.6d0) +
     x                  dexp((-v-132.d0)/18.d0))
            tauh = 60.d0 + 0.5d0/(dexp((v-1.33d0)/200.d0) +
     x                  dexp((-v-130.d0)/7.1d0))
             alpham_k2(i) = minf / taum
             betam_k2(i) = 1.d0/taum - alpham_k2(i)
             alphah_k2(i) = hinf / tauh
             betah_k2(i) = 1.d0 / tauh - alphah_k2(i)

c voltage part of C-current, using 1994 kinetics, shift 60 mV
              if (v.le.-10.d0) then
       alpham_kc(i) = (2.d0/37.95d0)*dexp((v+50.d0)/11.d0 -
     x                                     (v+53.5)/27.d0)
       betam_kc(i) = 2.d0*dexp((-v-53.5d0)/27.d0)-alpham_kc(i)
               else
       alpham_kc(i) = 2.d0*dexp((-v-53.5d0)/27.d0)
       betam_kc(i) = 0.d0
               endif

c high-threshold gCa, from 1994, with 60 mV shift & no inactivn.
            alpham_cal(i) = 1.6d0/(1.d0+dexp(-.072d0*(v-5.d0)))
            betam_cal(i) = 0.1d0 * ((v+8.9d0)/5.d0) /
     x          (dexp((v+8.9d0)/5.d0) - 1.d0)

c M-current, from plast.f, with 60 mV shift
        alpham_km(i) = .02d0/(1.d0+dexp((-v-20.d0)/5.d0))
        betam_km(i) = .01d0 * dexp((-v-43.d0)/18.d0)

c T-current, from Destexhe, Neubig et al., 1998
         minf = 1.d0/(1.d0 + dexp((-v-56.d0)/6.2d0))
         hinf = 1.d0/(1.d0 + dexp((v+80.d0)/4.d0))
         taum = 0.204d0 + .333d0/(dexp((v+15.8d0)/18.2d0) +
     x                  dexp((-v-131.d0)/16.7d0))
          if (v.le.-81.d0) then
         tauh = 0.333 * dexp((v+466.d0)/66.6d0)
          else
         tauh = 9.32d0 + 0.333d0*dexp((-v-21.d0)/10.5d0)
          endif
              alpham_cat(i) = minf / taum
              betam_cat(i) = 1.d0/taum - alpham_cat(i)
              alphah_cat(i) = hinf / tauh
              betah_cat(i) = 1.d0 / tauh - alphah_cat(i)

1        CONTINUE

         do  i = 0, 639

      dalpham_naf(i) = (alpham_naf(i+1)-alpham_naf(i))/.25d0
      dbetam_naf(i) = (betam_naf(i+1)-betam_naf(i))/.25d0
      dalphah_naf(i) = (alphah_naf(i+1)-alphah_naf(i))/.25d0
      dbetah_naf(i) = (betah_naf(i+1)-betah_naf(i))/.25d0
      dalpham_kdr(i) = (alpham_kdr(i+1)-alpham_kdr(i))/.25d0
      dbetam_kdr(i) = (betam_kdr(i+1)-betam_kdr(i))/.25d0
      dalpham_ka(i) = (alpham_ka(i+1)-alpham_ka(i))/.25d0
      dbetam_ka(i) = (betam_ka(i+1)-betam_ka(i))/.25d0
      dalphah_ka(i) = (alphah_ka(i+1)-alphah_ka(i))/.25d0
      dbetah_ka(i) = (betah_ka(i+1)-betah_ka(i))/.25d0
      dalpham_k2(i) = (alpham_k2(i+1)-alpham_k2(i))/.25d0
      dbetam_k2(i) = (betam_k2(i+1)-betam_k2(i))/.25d0
      dalphah_k2(i) = (alphah_k2(i+1)-alphah_k2(i))/.25d0
      dbetah_k2(i) = (betah_k2(i+1)-betah_k2(i))/.25d0
      dalpham_km(i) = (alpham_km(i+1)-alpham_km(i))/.25d0
      dbetam_km(i) = (betam_km(i+1)-betam_km(i))/.25d0
      dalpham_kc(i) = (alpham_kc(i+1)-alpham_kc(i))/.25d0
      dbetam_kc(i) = (betam_kc(i+1)-betam_kc(i))/.25d0
      dalpham_cat(i) = (alpham_cat(i+1)-alpham_cat(i))/.25d0
      dbetam_cat(i) = (betam_cat(i+1)-betam_cat(i))/.25d0
      dalphah_cat(i) = (alphah_cat(i+1)-alphah_cat(i))/.25d0
      dbetah_cat(i) = (betah_cat(i+1)-betah_cat(i))/.25d0
      dalpham_caL(i) = (alpham_cal(i+1)-alpham_cal(i))/.25d0
      dbetam_caL(i) = (betam_cal(i+1)-betam_cal(i))/.25d0
      dalpham_ar(i) = (alpham_ar(i+1)-alpham_ar(i))/.25d0
      dbetam_ar(i) = (betam_ar(i+1)-betam_ar(i))/.25d0
       end do
2      CONTINUE

         do i = 640, 640
      dalpham_naf(i) =  dalpham_naf(i-1)
      dbetam_naf(i) =  dbetam_naf(i-1)
      dalphah_naf(i) = dalphah_naf(i-1)
      dbetah_naf(i) = dbetah_naf(i-1)
      dalpham_kdr(i) =  dalpham_kdr(i-1)
      dbetam_kdr(i) =  dbetam_kdr(i-1)
      dalpham_ka(i) =  dalpham_ka(i-1)
      dbetam_ka(i) =  dbetam_ka(i-1)
      dalphah_ka(i) =  dalphah_ka(i-1)
      dbetah_ka(i) =  dbetah_ka(i-1)
      dalpham_k2(i) =  dalpham_k2(i-1)
      dbetam_k2(i) =  dbetam_k2(i-1)
      dalphah_k2(i) =  dalphah_k2(i-1)
      dbetah_k2(i) =  dbetah_k2(i-1)
      dalpham_km(i) =  dalpham_km(i-1)
      dbetam_km(i) =  dbetam_km(i-1)
      dalpham_kc(i) =  dalpham_kc(i-1)
      dbetam_kc(i) =  dbetam_kc(i-1)
      dalpham_cat(i) =  dalpham_cat(i-1)
      dbetam_cat(i) =  dbetam_cat(i-1)
      dalphah_cat(i) =  dalphah_cat(i-1)
      dbetah_cat(i) =  dbetah_cat(i-1)
      dalpham_caL(i) =  dalpham_caL(i-1)
      dbetam_caL(i) =  dbetam_caL(i-1)
      dalpham_ar(i) =  dalpham_ar(i-1)
      dbetam_ar(i) =  dbetam_ar(i-1)
       end do   

4000   END

        SUBROUTINE SCORTMAJ_suppyrRS
C BRANCHED ACTIVE DENDRITES
     X             (GL,GAM,GKDR,GKA,GKC,GKAHP,GK2,GKM,
     X              GCAT,GCAL,GNAF,GNAP,GAR,
     X    CAFOR,JACOB,C,BETCHI,NEIGH,NNUM,depth,level)
c Conductances: leak gL, coupling g, delayed rectifier gKDR, A gKA,
c C gKC, AHP gKAHP, K2 gK2, M gKM, low thresh Ca gCAT, high thresh
c gCAL, fast Na gNAF, persistent Na gNAP, h or anom. rectif. gAR.
c Note VAR = equil. potential for anomalous rectifier.
c Soma = comp. 1; 10 dendrites each with 13 compartments, 6-comp. axon
c Drop "glc"-like terms, just using "gl"-like
c CAFOR corresponds to "phi" in Traub et al., 1994
c Consistent set of units: nF, mV, ms, nA, microS

       INTEGER, PARAMETER:: numcomp = 74
! numcomp here must be compatible with numcomp_suppyrRS in calling prog.
        REAL*8 C(numcomp),GL(numcomp), GAM(0:numcomp, 0:numcomp)
        REAL*8 GNAF(numcomp),GCAT(numcomp), GKAHP(numcomp)
        REAL*8 GKDR(numcomp),GKA(numcomp),GKC(numcomp)
        REAL*8 GK2(numcomp),GNAP(numcomp),GAR(numcomp)
        REAL*8 GKM(numcomp), gcal(numcomp), CDENS
        REAL*8 JACOB(numcomp,numcomp),RI_SD,RI_AXON,RM_SD,RM_AXON
        INTEGER LEVEL(numcomp)
        REAL*8 GNAF_DENS(0:12), GCAT_DENS(0:12), GKDR_DENS(0:12)
        REAL*8 GKA_DENS(0:12), GKC_DENS(0:12), GKAHP_DENS(0:12)
        REAL*8 GCAL_DENS(0:12), GK2_DENS(0:12), GKM_DENS(0:12)
        REAL*8 GNAP_DENS(0:12), GAR_DENS(0:12)
        REAL*8 RES, RINPUT, Z, ELEN(numcomp)
        REAL*8 RSOMA, PI, BETCHI(numcomp), CAFOR(numcomp)
        REAL*8 RAD(numcomp), LEN(numcomp), GAM1, GAM2
        REAL*8 RIN, D(numcomp), AREA(numcomp), RI
        INTEGER NEIGH(numcomp,10), NNUM(numcomp), i, j, k, it
C FOR ESTABLISHING TOPOLOGY OF COMPARTMENTS
        real*8 depth(12) ! depth in microns of levels 1-12, assuming soma in middle
! of layer 2/3 at depth 850 mu

        depth(1) = 850.d0
        depth(2) = 885.d0
        depth(3) = 920.d0
        depth(4) = 955.d0
        depth(5) = 825.d0
        depth(6) = 775.d0
        depth(7) = 725.d0
        depth(8) = 690.d0
        depth(9) = 655.d0
        depth(10) = 620.d0
        depth(11) = 585.d0
        depth(12) = 550.d0

        RI_SD = 250.d0
        RM_SD = 50000.d0
        RI_AXON = 100.d0
        RM_AXON = 1000.d0
        CDENS = 0.9d0

        PI = 3.14159d0

       do i = 0, 12
        gnaf_dens(i) = 10.d0
       end do
c       gnaf_dens(0) = 400.d0
        gnaf_dens(0) = 120.d0
        gnaf_dens(1) = 120.d0
        gnaf_dens(2) =  75.d0
        gnaf_dens(5) = 100.d0
        gnaf_dens(6) =  75.d0

       do i = 0, 12
        gkdr_dens(i) = 0.d0
       end do
c       gkdr_dens(0) = 400.d0
        gkdr_dens(0) = 100.d0
        gkdr_dens(1) = 100.d0
        gkdr_dens(2) =  75.d0
        gkdr_dens(5) = 100.d0
        gkdr_dens(6) =  75.d0

        gnap_dens(0) = 0.d0
        do i = 1, 12
          gnap_dens(i) = 0.0040d0 * gnaf_dens(i)
c         gnap_dens(i) = 0.002d0 * gnaf_dens(i)
c         gnap_dens(i) = 0.0030d0 * gnaf_dens(i)
        end do

        gcat_dens(0) = 0.d0
        do i = 1, 12
c         gcat_dens(i) = 0.5d0
          gcat_dens(i) = 0.1d0
        end do

        gcaL_dens(0) = 0.d0
        do i = 1, 6
          gcaL_dens(i) = 0.5d0
        end do
        do i = 7, 12
          gcaL_dens(i) = 0.5d0
        end do

       do i = 0, 12
        gka_dens(i) = 2.d0
       end do
        gka_dens(1) = 30.d0
        gka_dens(5) = 30.d0

      do i = 0, 12
c        gkc_dens(i)  = 12.00d0
         gkc_dens(i)  =  0.00d0
c        gkc_dens(i)  =  2.00d0
c        gkc_dens(i)  =  7.00d0
      end do
         gkc_dens(0) =  0.00d0
         gkc_dens(1) = 7.5d0
         gkc_dens(2) = 7.5d0
         gkc_dens(5) = 7.5d0
         gkc_dens(6) = 7.5d0

        gkm_dens(0) = 2.d0 ! 9 Nov. 2005, see scort-pan.f of today
! Above suppresses doublets, but still allows FRB with appropriate
! gNaP, gKC, and rel_axonshift (e.g. 6 mV)
        do i = 1, 12
         gkm_dens(i) = 2.5d0 * 1.50d0
        end do

        do i = 0, 12
c       gk2_dens(i) = 1.d0
        gk2_dens(i) = 0.1d0
        end do
        gk2_dens(0) = 0.d0

        gkahp_dens(0) = 0.d0
        do i = 1, 12
c        gkahp_dens(i) = 0.200d0
         gkahp_dens(i) = 0.100d0
c        gkahp_dens(i) = 0.050d0
        end do

        gar_dens(0) = 0.d0
        do i = 1, 12
         gar_dens(i) = 0.25d0
        end do

c       WRITE   (6,9988)
9988    FORMAT(2X,'I',4X,'NADENS',' CADENS(T)',' KDRDEN',' KAHPDE',
     X     ' KCDENS',' KADENS')
        DO 9989, I = 0, 12
c         WRITE (6,9990) I, gnaf_dens(i), gcat_dens(i), gkdr_dens(i),
c    X  gkahp_dens(i), gkc_dens(i), gka_dens(i)
9990    FORMAT(2X,I2,2X,F6.2,1X,F6.2,1X,F6.2,1X,F6.2,1X,F6.2,1X,F6.2)
9989    CONTINUE


        level(1) = 1
        do i = 2, 13
         level(i) = 2
        end do
        do i = 14, 25
           level(i) = 3
        end do
        do i = 26, 37
           level(i) = 4
        end do
        level(38) = 5
        level(39) = 6
        level(40) = 7
        level(41) = 8
        level(42) = 8
        level(43) = 9
        level(44) = 9
        do i = 45, 52
           level(i) = 10
        end do
        do i = 53, 60
           level(i) = 11
        end do
        do i = 61, 68
           level(i) = 12
        end do

        do i =  69, 74
         level(i) = 0
        end do

c connectivity of axon
        nnum( 69) = 2
        nnum( 70) = 3
        nnum( 71) = 3
        nnum( 73) = 3
        nnum( 72) = 1
        nnum( 74) = 1
         neigh(69,1) =  1
         neigh(69,2) = 70
         neigh(70,1) = 69
         neigh(70,2) = 71
         neigh(70,3) = 73
         neigh(71,1) = 70
         neigh(71,2) = 72
         neigh(71,3) = 73
         neigh(73,1) = 70
         neigh(73,2) = 71
         neigh(73,3) = 74
         neigh(72,1) = 71
         neigh(74,1) = 73

c connectivity of SD part
          nnum(1) = 10
          neigh(1,1) = 69
          neigh(1,2) =  2
          neigh(1,3) =  3
          neigh(1,4) =  4
          neigh(1,5) =  5
          neigh(1,6) =  6
          neigh(1,7) =  7
          neigh(1,8) =  8
          neigh(1,9) =  9
          neigh(1,10) = 38

          do i = 2, 9
           nnum(i) = 2
           neigh(i,1) = 1
           neigh(i,2) = i + 12
          end do

          do i = 14, 21
            nnum(i) = 2
            neigh(i,1) = i - 12
            neigh(i,2) = i + 12
          end do

          do i = 26, 33
            nnum(i) = 1
            neigh(i,1) = i - 12
          end do

          do i = 10, 13
            nnum(i) = 2
            neigh(i,1) = 38
            neigh(i,2) = i + 12
          end do

          do i = 22, 25
            nnum(i) = 2
            neigh(i,1) = i - 12
            neigh(i,2) = i + 12
          end do

          do i = 34, 37
            nnum(i) = 1
            neigh(i,1) = i - 12
          end do

          nnum(38) = 6
          neigh(38,1) = 1
          neigh(38,2) = 39
          neigh(38,3) = 10
          neigh(38,4) = 11
          neigh(38,5) = 12
          neigh(38,6) = 13

          nnum(39) = 2
          neigh(39,1) = 38
          neigh(39,2) = 40

          nnum(40) = 3
          neigh(40,1) = 39
          neigh(40,2) = 41
          neigh(40,3) = 42

          nnum(41) = 3
          neigh(41,1) = 40
          neigh(41,2) = 42
          neigh(41,3) = 43

          nnum(42) = 3
          neigh(42,1) = 40
          neigh(42,2) = 41
          neigh(42,3) = 44

           nnum(43) = 5
           neigh(43,1) = 41
           neigh(43,2) = 45
           neigh(43,3) = 46
           neigh(43,4) = 47
           neigh(43,5) = 48

           nnum(44) = 5
           neigh(44,1) = 42
           neigh(44,2) = 49
           neigh(44,3) = 50
           neigh(44,4) = 51
           neigh(44,5) = 52

           nnum(45) = 5
           neigh(45,1) = 43
           neigh(45,2) = 53
           neigh(45,3) = 46
           neigh(45,4) = 47
           neigh(45,5) = 48

           nnum(46) = 5
           neigh(46,1) = 43
           neigh(46,2) = 54
           neigh(46,3) = 45
           neigh(46,4) = 47
           neigh(46,5) = 48

           nnum(47) = 5
           neigh(47,1) = 43
           neigh(47,2) = 55
           neigh(47,3) = 45
           neigh(47,4) = 46
           neigh(47,5) = 48

           nnum(48) = 5
           neigh(48,1) = 43
           neigh(48,2) = 56
           neigh(48,3) = 45
           neigh(48,4) = 46
           neigh(48,5) = 47

           nnum(49) = 5
           neigh(49,1) = 44
           neigh(49,2) = 57
           neigh(49,3) = 50
           neigh(49,4) = 51
           neigh(49,5) = 52

           nnum(50) = 5
           neigh(50,1) = 44
           neigh(50,2) = 58
           neigh(50,3) = 49
           neigh(50,4) = 51
           neigh(50,5) = 52

           nnum(51) = 5
           neigh(51,1) = 44
           neigh(51,2) = 59
           neigh(51,3) = 49
           neigh(51,4) = 50
           neigh(51,5) = 52

           nnum(52) = 5
           neigh(52,1) = 44
           neigh(52,2) = 60
           neigh(52,3) = 49
           neigh(52,4) = 51
           neigh(52,5) = 50

          do i = 53, 60
           nnum(i) = 2
           neigh(i,1) = i - 8
           neigh(i,2) = i + 8
          end do

          do i = 61, 68
           nnum(i) = 1
           neigh(i,1) = i - 8
          end do

c        DO 332, I = 1, 74
         DO I = 1, 74
c          WRITE(6,3330) I, NEIGH(I,1),NEIGH(I,2),NEIGH(I,3),NEIGH(I,4),
c    X NEIGH(I,5),NEIGH(I,6),NEIGH(I,7),NEIGH(I,8),NEIGH(I,9),
c    X NEIGH(I,10)
3330     FORMAT(2X,11I5)
         END DO
332      CONTINUE
c         DO 858, I = 1, 74
          DO I = 1, 74
c          DO 858, J = 1, NNUM(I)
           DO J = 1, NNUM(I)
            K = NEIGH(I,J)
            IT = 0
c           DO 859, L = 1, NNUM(K)
            DO  L = 1, NNUM(K)
             IF (NEIGH(K,L).EQ.I) IT = 1
            END DO
859         CONTINUE
             IF (IT.EQ.0) THEN
c             WRITE(6,8591) I, K
8591          FORMAT(' ASYMMETRY IN NEIGH MATRIX ',I4,I4)
              STOP
             ENDIF
          END DO
          END DO
858       CONTINUE

c length and radius of axonal compartments
c Note shortened "initial segment"
          len(69) = 25.d0
          do i = 70, 74
            len(i) = 50.d0
          end do
          rad( 69) = 0.90d0
c         rad( 69) = 0.80d0
          rad( 70) = 0.7d0
          do i = 71, 74
           rad(i) = 0.5d0
          end do

c  length and radius of SD compartments
          len(1) = 15.d0
          rad(1) =  8.d0

          do i = 2, 68
           len(i) = 50.d0
          end do

          do i = 2, 37
            rad(i) = 0.5d0
          end do

          z = 4.0d0
          rad(38) = z
          rad(39) = 0.9d0 * z
          rad(40) = 0.8d0 * z
          rad(41) = 0.5d0 * z
          rad(42) = 0.5d0 * z
          rad(43) = 0.5d0 * z
          rad(44) = 0.5d0 * z
          do i = 45, 68
           rad(i) = 0.2d0 * z
          end do


c       WRITE(6,919)
919     FORMAT('COMPART.',' LEVEL ',' RADIUS ',' LENGTH(MU)')
c       DO 920, I = 1, 74
c920      WRITE(6,921) I, LEVEL(I), RAD(I), LEN(I)
921     FORMAT(I3,5X,I2,3X,F6.2,1X,F6.1,2X,F4.3)

        DO 120, I = 1, 74
          AREA(I) = 2.d0 * PI * RAD(I) * LEN(I)
      if((i.gt.1).and.(i.le.68)) area(i) = 2.d0 * area(i)
C    CORRECTION FOR CONTRIBUTION OF SPINES TO AREA
          K = LEVEL(I)
          C(I) = CDENS * AREA(I) * (1.D-8)

           if (k.ge.1) then
          GL(I) = (1.D-2) * AREA(I) / RM_SD
           else
          GL(I) = (1.D-2) * AREA(I) / RM_AXON
           endif

          GNAF(I) = GNAF_DENS(K) * AREA(I) * (1.D-5)
          GNAP(I) = GNAP_DENS(K) * AREA(I) * (1.D-5)
          GCAT(I) = GCAT_DENS(K) * AREA(I) * (1.D-5)
          GKDR(I) = GKDR_DENS(K) * AREA(I) * (1.D-5)
          GKA(I) = GKA_DENS(K) * AREA(I) * (1.D-5)
          GKC(I) = GKC_DENS(K) * AREA(I) * (1.D-5)
          GKAHP(I) = GKAHP_DENS(K) * AREA(I) * (1.D-5)
          GKM(I) = GKM_DENS(K) * AREA(I) * (1.D-5)
          GCAL(I) = GCAL_DENS(K) * AREA(I) * (1.D-5)
          GK2(I) = GK2_DENS(K) * AREA(I) * (1.D-5)
          GAR(I) = GAR_DENS(K) * AREA(I) * (1.D-5)
c above conductances should be in microS
120           continue

         Z = 0.d0
c        DO 1019, I = 2, 68
         DO I = 2, 68
           Z = Z + AREA(I)
         END DO
1019     CONTINUE
c        WRITE(6,1020) Z
1020     FORMAT(2X,' TOTAL DENDRITIC AREA ',F7.0)

c       DO 140, I = 1, 74
        DO I = 1, 74
c       DO 140, K = 1, NNUM(I)
        DO K = 1, NNUM(I)
         J = NEIGH(I,K)
           if (level(i).eq.0) then
               RI = RI_AXON
           else
               RI = RI_SD
           endif
         GAM1 =100.d0 * PI * RAD(I) * RAD(I) / ( RI * LEN(I) )

           if (level(j).eq.0) then
               RI = RI_AXON
           else
               RI = RI_SD
           endif
         GAM2 =100.d0 * PI * RAD(J) * RAD(J) / ( RI * LEN(J) )
         GAM(I,J) = 2.d0/( (1.d0/GAM1) + (1.d0/GAM2) )
	 END DO
	 END DO

140     CONTINUE
c gam computed in microS

c       DO 299, I = 1, 74
        DO I = 1, 74
299       BETCHI(I) = .05d0
        END DO
        BETCHI( 1) =  .01d0

c       DO 300, I = 1, 74
        DO I = 1, 74
c300     D(I) = 2.D-4
300     D(I) = 5.D-4
        END DO
c       DO 301, I = 1, 74
        DO I = 1, 74
         IF (LEVEL(I).EQ.1) D(I) = 2.D-3
        END DO
301     CONTINUE
C  NOTE NOTE NOTE  (DIFFERENT FROM SWONG)


c      DO 160, I = 1, 74
       DO I = 1, 74
160     CAFOR(I) = 5200.d0 / (AREA(I) * D(I))
       END DO
C     NOTE CORRECTION

c       do 200, i = 1, 74
        do i = 1, numcomp
200     C(I) = 1000.d0 * C(I)
        end do
C     TO GO FROM MICROF TO NF.

c     DO 909, I = 1, 74
      DO I = 1, numcomp
       JACOB(I,I) = - GL(I)
c     DO 909, J = 1, NNUM(I)
      DO J = 1, NNUM(I)
         K = NEIGH(I,J)
         IF (I.EQ.K) THEN
c            WRITE(6,510) I
510          FORMAT(' UNEXPECTED SYMMETRY IN NEIGH ',I4)
         ENDIF
         JACOB(I,K) = GAM(I,K)
         JACOB(I,I) = JACOB(I,I) - GAM(I,K)
       END DO
       END DO
909   CONTINUE

c 15 Jan. 2001: make correction for c(i)
          do i = 1, numcomp
          do j = 1, numcomp
             jacob(i,j) = jacob(i,j) / c(i)
          end do
          end do

c      DO 500, I = 1, 74
       DO I = 1, 74
c       WRITE (6,501) I,C(I)
501     FORMAT(1X,I3,' C(I) = ',F7.4)
       END DO
500     CONTINUE
        END

! 9 Sept. 2006: start with integrate_nontuftRSXX.f from isoldeepVFOK, and
! add GABA-B
c 31 Mar. 2005, modify with lower axonal fast gNa, shift axonal gNaF
c 11 Oct. 2004, allow for some of the cells (highest nontuftRS_nFRB
c of them) to be FRB, with altered gNaP, gKC & gCaL - see
c layVtup.f.3Feb04

c 3 Nov. 2003, modify layVrsp.f (layer 5 nontufted. pyr cell with thin
c apical dendrite), for use in groucho.f

c 14 May 2003.  Copy program from Rose and modify for mpi.
c 19 June 2001. Taken from scortpd.f.  Parallel.
c 19 June 2001: layer V RS cell with "thin" dendrite, no apical tuft.
c See Kim & Connors, Mason & Larkman.
c 44 SD compartments, 6 axonal, total 50.
c 5 basal and 6 apical oblique dendrites, each with 3 compartments.
c 10-compartment apical dendrite, no branches (apart from obliques)

c 13 April 2001, version of scortp.f, for looking at dendritic activities.
c  7 April 2001, parallel version of scort.f
c 30 March 2001: layer 2/3 pyramidal cell, with geometry (as much as
c possible) from Guy Major thesis; start with tcr.f.
c Total 74 compartments: 6 axon.  8 basal and 3 oblique dendrites, each
c with 3 compartments: apical shaft and branch; 8 3-segment pieces in
c the "apical tuft".

c Revised tcr.f, using modifications developed in short.f
c 22 Feb. 2001: alter persistent gNaP to have lower threshold and
c 1st power activation; in addition, try increasing activation
c threshold of fast gNa, as per Parri & Crunelli 1998.
c 25 Jan. 2001, single TCR cell, modification of nrt.f
c TCR cell has 10 short dendrites, each with 13 compartments.
c Soma is compartment 1; axon is 132-137, with structure as in
c  nRT cell model.  Each dendrite has 2 layers of trifurcations.

c 28 Dec. 2000, begin converting interneuron program to nRT cell.
c Soma will be comp. 1.  4 equivalent dendrites, each with 13 comps.
c (so 53 SD compartments).  Branching axon with 6 compartments - 59
c compartments in all.  Try one integration program for whole structure.
c Currents: leak, fast Na (naf), persistent Na (nap), fast DR (kdr),
c A-current (ka), K2 current, M-current (km), C current (kc), AHP
c (kahp), T-current (cat), high-thresh. Ca (CAL), h-current = anomalous
c rectifier (ar).

         SUBROUTINE integrate_nontuftRSXXB (O, time, numcell, V, curr,
     &    initialize, firstcell, lastcell,
     &    gAMPA, gNMDA, gGABA_A, gGABA_B,
     &    Mg, gapcon, totaxgj, gjtable, dt,
     &  chi,mnaf,mnap,
     &  hnaf,mkdr,mka,
     &  hka,mk2,hk2,
     &  mkm,mkc,mkahp,
     &  mcat,hcat,mcal,
     &  mar,field_1mm,field_2mm,
     &  nontuftRS_nFRB)

         SAVE

         integer, parameter:: numcomp = 50
c numcomp = number of compartments, including 6 in the axon.

       integer numcell, totaxgj, gjtable(totaxgj,4)
       integer initialize, firstcell, lastcell
       INTEGER J1, I, J, K, L, O, k0, K1, k2, nontuftRS_nFRB
       REAL*8  Z, Z1, Z2, Z3, curr(numcomp,numcell)
       REAL*8  mg, time, gapcon, dt, c(numcomp)

c CINV is 1/C, i.e. inverse capacitance

       real*8 v(numcomp,numcell),chi(numcomp,numcell),
     x  mnaf(numcomp,numcell),mnap(numcomp,numcell),
     x hnaf(numcomp,numcell),mkdr(numcomp,numcell),
     x mka(numcomp,numcell),hka(numcomp,numcell),
     x mk2(numcomp,numcell), cinv(numcomp),
     x hk2(numcomp,numcell),mkm(numcomp,numcell),
     x mkc(numcomp,numcell),mkahp(numcomp,numcell),
     x mcat(numcomp,numcell),hcat(numcomp,numcell),
     x mcal(numcomp,numcell),
     x mar(numcomp,numcell),
     x jacob(numcomp,numcomp),betchi(numcomp),
     x gam(0: numcomp,0: numcomp),gL(numcomp),gnaf(numcomp),
     x gnap(numcomp),gkdr(numcomp),gka(numcomp),
     x gk2(numcomp),gkm(numcomp),gkc(numcomp),gkahp(numcomp),
     x gcat(numcomp),gcaL(numcomp),gar(numcomp),
     x gampa(numcomp,numcell),gnmda(numcomp,numcell),
     x ggaba_a(numcomp,numcell),cafor(numcomp),
     x ggaba_b(numcomp,numcell)

! define separate conductance parameters for RS vs FRB behaviors
        real*8 gnap_FRB(numcomp), gkc_FRB(numcomp), gcal_FRB(numcomp)
        real*8 gnap_RS(numcomp), gkc_RS(numcomp), gcal_RS(numcomp)

       real*8
     X alpham_naf(0:640),betam_naf(0:640),dalpham_naf(0:640),
     X   dbetam_naf(0:640),
     X alphah_naf(0:640),betah_naf(0:640),dalphah_naf(0:640),
     X   dbetah_naf(0:640),
     X alpham_kdr(0:640),betam_kdr(0:640),dalpham_kdr(0:640),
     X   dbetam_kdr(0:640),
     X alpham_ka(0:640), betam_ka(0:640),dalpham_ka(0:640) ,
     X   dbetam_ka(0:640),
     X alphah_ka(0:640), betah_ka(0:640), dalphah_ka(0:640),
     X   dbetah_ka(0:640),
     X alpham_k2(0:640), betam_k2(0:640), dalpham_k2(0:640),
     X   dbetam_k2(0:640),
     X alphah_k2(0:640), betah_k2(0:640), dalphah_k2(0:640),
     X   dbetah_k2(0:640),
     X alpham_km(0:640), betam_km(0:640), dalpham_km(0:640),
     X   dbetam_km(0:640),
     X alpham_kc(0:640), betam_kc(0:640), dalpham_kc(0:640),
     X   dbetam_kc(0:640),
     X alpham_cat(0:640),betam_cat(0:640),dalpham_cat(0:640),
     X   dbetam_cat(0:640),
     X alphah_cat(0:640),betah_cat(0:640),dalphah_cat(0:640),
     X   dbetah_cat(0:640),
     X alpham_caL(0:640),betam_caL(0:640),dalpham_caL(0:640),
     X   dbetam_caL(0:640),
     X alpham_ar(0:640), betam_ar(0:640), dalpham_ar(0:640),
     X   dbetam_ar(0:640)
       real*8 vL(numcomp),vk(numcomp),vna,var,vca,vgaba_a
       real*8 outrcd(20), A, BB1, BB2

        INTEGER NEIGH(numcomp, 7), NNUM(numcomp)

c the f's are the functions giving 1st derivatives for evolution of
c the differential equations for the voltages (v), calcium (chi), and
c other state variables.
       real*8 fv(numcomp), fchi(numcomp),
     x fmnaf(numcomp),fhnaf(numcomp),fmkdr(numcomp),
     x fmka(numcomp),fhka(numcomp),fmar(numcomp),
     x fmk2(numcomp),fhk2(numcomp),fmnap(numcomp),
     x fmkm(numcomp),fmkc(numcomp),fmkahp(numcomp),
     x fmcat(numcomp),fhcat(numcomp),fmcal(numcomp)

c below are for calculating the partial derivatives
       real*8 dfv_dv(numcomp,numcomp), dfv_dchi(numcomp),
     x    dfv_dmnaf(numcomp),
     x    dfv_dmnap(numcomp),
     x  dfv_dhnaf(numcomp),dfv_dmkdr(numcomp),
     x  dfv_dmka(numcomp),dfv_dhka(numcomp),
     x  dfv_dmk2(numcomp),dfv_dhk2(numcomp),
     x  dfv_dmkm(numcomp),dfv_dmkc(numcomp),
     x  dfv_dmkahp(numcomp),dfv_dmcat(numcomp),
     x  dfv_dhcat(numcomp),dfv_dmcal(numcomp),
     x  dfv_dmar(numcomp)

        real*8 dfchi_dv(numcomp), dfchi_dchi(numcomp),
     x dfmnaf_dmnaf(numcomp), dfmnaf_dv(numcomp),
     x dfhnaf_dhnaf(numcomp),
     x dfmnap_dmnap(numcomp), dfmnap_dv(numcomp),
     x dfhnaf_dv(numcomp),dfmkdr_dmkdr(numcomp),
     x dfmkdr_dv(numcomp),
     x dfmka_dmka(numcomp),dfmka_dv(numcomp),
     x dfhka_dhka(numcomp),dfhka_dv(numcomp),
     x dfmk2_dmk2(numcomp),dfmk2_dv(numcomp),
     x dfhk2_dhk2(numcomp),dfhk2_dv(numcomp),
     x dfmkm_dmkm(numcomp),dfmkm_dv(numcomp),
     x dfmkc_dmkc(numcomp),dfmkc_dv(numcomp),
     x dfmcat_dmcat(numcomp),dfmcat_dv(numcomp),
     x dfhcat_dhcat(numcomp),
     x dfhcat_dv(numcomp),dfmcal_dmcal(numcomp),
     x dfmcal_dv(numcomp),
     x dfmar_dmar(numcomp),dfmar_dv(numcomp),
     x dfmkahp_dchi(numcomp),
     x dfmkahp_dmkahp(numcomp), dt2

       REAL*8 OPEN(numcomp),gamma(numcomp),gamma_prime(numcomp)
c gamma is function of chi used in calculating KC conductance
       REAL*8 alpham_ahp(numcomp), alpham_ahp_prime(numcomp)
       REAL*8 gna_tot(numcomp),gk_tot(numcomp)
       REAL*8 gca_tot(numcomp),gar_tot(numcomp)
       REAL*8 gca_high(numcomp)
c this will be gCa conductance corresponding to high-thresh channels
       real*8 depth(14), membcurr(14), field_1mm, field_2mm
       integer level(numcomp)

       double precision:: persistentNa_shift, fastNa_shift_SD
       double precision::                     fastNa_shift_axon

c Do initialization on 1st time step
        if (initialize.eq.0) then
c       if (O.eq.1) then

c Program assumes A, BB1, BB2 defined in calling program
c as follows:
         A = DEXP(-2.847d0)
         BB1 = DEXP(-.693d0)
         BB2 = DEXP(-3.101d0)

       CALL  nontuftRS_SETUP
     X   (alpham_naf, betam_naf, dalpham_naf, dbetam_naf,
     X    alphah_naf, betah_naf, dalphah_naf, dbetah_naf,
     X    alpham_kdr, betam_kdr, dalpham_kdr, dbetam_kdr,
     X    alpham_ka , betam_ka , dalpham_ka , dbetam_ka ,
     X    alphah_ka , betah_ka , dalphah_ka , dbetah_ka ,
     X    alpham_k2 , betam_k2 , dalpham_k2 , dbetam_k2 ,
     X    alphah_k2 , betah_k2 , dalphah_k2 , dbetah_k2 ,
     X    alpham_km , betam_km , dalpham_km , dbetam_km ,
     X    alpham_kc , betam_kc , dalpham_kc , dbetam_kc ,
     X    alpham_cat, betam_cat, dalpham_cat, dbetam_cat,
     X    alphah_cat, betah_cat, dalphah_cat, dbetah_cat,
     X    alpham_caL, betam_caL, dalpham_caL, dbetam_caL,
     X    alpham_ar , betam_ar , dalpham_ar , dbetam_ar)

        CALL nontuftRSMAJ (GL,GAM,GKDR,GKA,GKC,GKAHP,GK2,GKM,
     X              GCAT,GCAL,GNAF,GNAP,GAR,
     X    CAFOR,JACOB,C,BETCHI,NEIGH,NNUM,depth,level)

          do i = 1, numcomp
             cinv(i) = 1.d0 / c(i)
          end do

             vL = -70.d0

             vK = -95.d0

        VNA = 50.d0
        VCA = 125.d0
        VAR = -43.d0
        VAR = -35.d0
c -43 mV from Huguenard & McCormick
c       VGABA_A = -81.d0
        VGABA_A = -75.d0


c ? initialize membrane state variables?
        v = VL(1)

        k1 = idnint (4.d0 * (v(1,1) + 120.d0))

      hnaf = alphah_naf(k1)/(alphah_naf(k1)+betah_naf(k1))
      hka = alphah_ka(k1)/(alphah_ka(k1)+betah_ka(k1))
      hk2 = alphah_k2(k1)/(alphah_k2(k1)+betah_k2(k1))
      hcat=alphah_cat(k1)/(alphah_cat(k1)+betah_cat(k1))
c     mar=alpham_ar(k1)/(alpham_ar(k1)+betam_ar(k1))
      mar= .25d0
      mnaf = 0.d0
      mkdr = 0.d0
      mka = 0.d0
      mk2 = 0.d0
      mkm = 0.d0
      mkc = 0.d0
      mkahp = 0.d0
      mcat = 0.d0
      mcal = 0.d0
      mnap = 0.d0
      chi = 0.d0

           z1 = 0.10d0
c          z2 = 2.0d0
           z2 = 1.0d0
c This should give an RS cell?

! 1st scale for FRB cells
             do i = 1, numcomp
          gnap_FRB(i) = 1.2d0 * gnap(i)
          gkc_FRB(i)  = 1.d0  * gkc(i)
          gcal_FRB(i) = 0.4d0 * gcal(i)
             end do

! now scale for RS cells
             do i = 1, numcomp
         gnap_RS(i) = z1 * gnap(i)
         gkc_RS (i) = z2 * gkc (i)
         gcal_RS(i) = gcal(i)
             end do

           goto 4000

      endif !  End initialization

             do i = 1, 14
              membcurr(i) = 0.d0
             end do

c         do L = 1, numcell
          do L = firstcell, lastcell

           if (L.le.(numcell - nontuftRS_nFRB)) then
              gnap = gnap_RS
              gkc = gkc_RS
              gcal = gcal_RS
           else
              gnap = gnap_FRB
              gkc  = gkc_FRB
              gcal = gcal_FRB
           endif  

       DO 301, I = 1, numcomp
          FV(I) = -GL(I) * (V(I,L) - VL(i)) * cinv(i)
          DO 302, J = 1, NNUM(I)
             K = NEIGH(I,J)
302     FV(I) = FV(I) + GAM(I,K) * (V(K,L) - V(I,L)) * cinv(i)
301    CONTINUE


        CALL FNMDA (V, OPEN, numcell, numcomp, MG, L, 
     &    A, BB1, BB2)

      DO 421, I = 1, numcomp
       FV(I) = FV(I) + ( CURR(I,L)
     X   - (gampa(I,L) + open(i) * gnmda(I,L))*V(I,L)
     X   - ggaba_a(I,L)*(V(I,L)-Vgaba_a) 
     X   - ggaba_b(I,L)*(V(I,L)-VK(i)  ) ) * cinv(i)
c above assumes equil. potential for AMPA & NMDA = 0 mV
421      continue

! gj code here

       do m = 1, totaxgj
        if (gjtable(m,1).eq.L) then
         L1 = gjtable(m,3)
         igap1 = gjtable(m,2)
         igap2 = gjtable(m,4)
 	fv(igap1) = fv(igap1) + gapcon *
     &   (v(igap2,L1) - v(igap1,L)) * cinv(igap1)
        else if (gjtable(m,3).eq.L) then
         L1 = gjtable(m,1)
         igap1 = gjtable(m,4)
         igap2 = gjtable(m,2)
 	fv(igap1) = fv(igap1) + gapcon *
     &   (v(igap2,L1) - v(igap1,L)) * cinv(igap1)
        endif
       end do ! do m

       do i = 1, numcomp
        gamma(i) = dmin1 (1.d0, .004d0 * chi(i,L))
        if (chi(i,L).le.250.d0) then
          gamma_prime(i) = .004d0
        else
          gamma_prime(i) = 0.d0
        endif
c         endif
       end do

      DO 88, I = 1, numcomp
       gna_tot(i) = gnaf(i) * (mnaf(i,L)**3) * hnaf(i,L) +
     x     gnap(i) * mnap(i,L)
       gk_tot(i) = gkdr(i) * (mkdr(i,L)**4) +
     x             gka(i)  * (mka(i,L)**4) * hka(i,L) +
     x             gk2(i)  * mk2(i,L) * hk2(i,L) +
     x             gkm(i)  * mkm(i,L) +
     x             gkc(i)  * mkc(i,L) * gamma(i) +
     x             gkahp(i)* mkahp(i,L)
       gca_tot(i) = gcat(i) * (mcat(i,L)**2) * hcat(i,L) +
     x              gcaL(i) * (mcaL(i,L)**2)
       gca_high(i) =
     x              gcaL(i) * (mcaL(i,L)**2)
       gar_tot(i) = gar(i) * mar(i,L)


       FV(I) = FV(I) - ( gna_tot(i) * (v(i,L) - vna)
     X  + gk_tot(i) * (v(i,L) - vK(i))
     X  + gca_tot(i) * (v(i,L) - vCa)
     X  + gar_tot(i) * (v(i,L) - var) ) * cinv(i)
c        endif
88           continue

         do i = 1, numcomp
         do j = 1, numcomp
          if (i.ne.j) then
            dfv_dv(i,j) = jacob(i,j)
          else
            dfv_dv(i,j) = jacob(i,i) - cinv(i) *
     X  (gna_tot(i) + gk_tot(i) + gca_tot(i) + gar_tot(i)
     X   + ggaba_a(i,L) + ggaba_b(i,L) + gampa(i,L)
     X   + open(i) * gnmda(I,L) )
          endif
         end do
         end do

           do i = 1, numcomp
        dfv_dchi(i)  = - cinv(i) * gkc(i) * mkc(i,L) *
     x                     gamma_prime(i) * (v(i,L)-vK(i))
        dfv_dmnaf(i) = -3.d0 * cinv(i) * (mnaf(i,L)**2) *
     X    (gnaf(i) * hnaf(i,L)          ) * (v(i,L) - vna)
        dfv_dmnap(i) = - cinv(i) *
     X    (               gnap(i)) * (v(i,L) - vna)
        dfv_dhnaf(i) = - cinv(i) * gnaf(i) * (mnaf(i,L)**3) *
     X                    (v(i,L) - vna)
        dfv_dmkdr(i) = -4.d0 * cinv(i) * gkdr(i) * (mkdr(i,L)**3)
     X                   * (v(i,L) - vK(i))
        dfv_dmka(i)  = -4.d0 * cinv(i) * gka(i) * (mka(i,L)**3) *
     X                   hka(i,L) * (v(i,L) - vK(i))
        dfv_dhka(i)  = - cinv(i) * gka(i) * (mka(i,L)**4) *
     X                    (v(i,L) - vK(i))
        dfv_dmk2(i)  = - cinv(i)*gk2(i)*hk2(i,L)*(v(i,L)-vK(i))
        dfv_dhk2(i)  = - cinv(i)*gk2(i)*mk2(i,L)*(v(i,L)-vK(i))
        dfv_dmkm(i)  = - cinv(i) * gkm(i) * (v(i,L) - vK(i))
      dfv_dmkc(i) = - cinv(i) * gkc(i) * gamma(i)*(v(i,L)-vK(i))
        dfv_dmkahp(i)= - cinv(i) * gkahp(i) * (v(i,L) - vK(i))
        dfv_dmcat(i)  = -2.d0 * cinv(i) * gcat(i) * mcat(i,L) *
     X                    hcat(i,L) * (v(i,L) - vCa)
        dfv_dhcat(i) = - cinv(i) * gcat(i) * (mcat(i,L)**2) *
     X                  (v(i,L) - vCa)
        dfv_dmcal(i) = -2.d0 * cinv(i) * gcal(i) * mcal(i,L) *
     X                      (v(i,L) - vCa)
        dfv_dmar(i) = - cinv(i) * gar(i) * (v(i,L) - var)
            end do

         do i = 1, numcomp
          fchi(i) = - cafor(i) * gca_high(i) * (v(i,L) - vca)
     x       - betchi(i) * chi(i,L)
          dfchi_dv(i) = - cafor(i) * gca_high(i)
          dfchi_dchi(i) = - betchi(i)
         end do

       do i = 1, numcomp
c Note possible increase in rate at which AHP current develops
c       alpham_ahp(i) = dmin1(0.2d-4 * chi(i),0.01d0)
        alpham_ahp(i) = dmin1(1.0d-4 * chi(i,L),0.01d0)
        if (chi(i,L).le.500.d0) then
c         alpham_ahp_prime(i) = 0.2d-4
          alpham_ahp_prime(i) = 1.0d-4
        else
          alpham_ahp_prime(i) = 0.d0
        endif
       end do

       do i = 1, numcomp
        fmkahp(i) = alpham_ahp(i) * (1.d0 - mkahp(i,L))
     x                  -.001d0 * mkahp(i,L)
c    x                  -.010d0 * mkahp(i,L)
        dfmkahp_dmkahp(i) = - alpham_ahp(i) - .001d0
c       dfmkahp_dmkahp(i) = - alpham_ahp(i) - .010d0
        dfmkahp_dchi(i) = alpham_ahp_prime(i) *
     x                     (1.d0 - mkahp(i,L))
       end do

          do i = 1, numcomp

       K1 = IDNINT ( 4.d0 * (V(I,L) + 120.d0) )
       IF (K1.GT.640) K1 = 640
       IF (K1.LT.  0) K1 =   0

c      persistentNa_shift =  0.d0
c      persistentNa_shift =  8.d0
       persistentNa_shift = 10.d0
       K2 = IDNINT ( 4.d0 * (V(I,L)+persistentNa_shift+ 120.d0) )
       IF (K2.GT.640) K2 = 640
       IF (K2.LT.  0) K2 =   0

c            fastNa_shift = -2.0d0
c            fastNa_shift = -2.5d0
             fastNa_shift_SD = -3.5d0
             fastNa_shift_axon = fastNa_shift_SD + 7.d0
       K0 = IDNINT ( 4.d0 * (V(I,L)+  fastNa_shift_SD+ 120.d0) )
       K3 = IDNINT ( 4.d0 * (V(I,L)+  fastNa_shift_axon+ 120.d0) )
       IF (K0.GT.640) K0 = 640
       IF (K0.LT.  0) K0 =   0
       IF (K3.GT.640) K3 = 640
       IF (K3.LT.  0) K3 =   0

         if (i.le.44) then
        fmnaf(i) = alpham_naf(k0) * (1.d0 - mnaf(i,L)) -
     X              betam_naf(k0) * mnaf(i,L)
        fhnaf(i) = alphah_naf(k0) * (1.d0 - hnaf(i,L)) -
     X              betah_naf(k0) * hnaf(i,L)
         else
        fmnaf(i) = alpham_naf(k3) * (1.d0 - mnaf(i,L)) -
     X              betam_naf(k3) * mnaf(i,L)
        fhnaf(i) = alphah_naf(k3) * (1.d0 - hnaf(i,L)) -
     X              betah_naf(k3) * hnaf(i,L)
         endif


        fmnap(i) = alpham_naf(k2) * (1.d0 - mnap(i,L)) -
     X              betam_naf(k2) * mnap(i,L)
        fmkdr(i) = alpham_kdr(k1) * (1.d0 - mkdr(i,L)) -
     X              betam_kdr(k1) * mkdr(i,L)
        fmka(i)  = alpham_ka (k1) * (1.d0 - mka(i,L)) -
     X              betam_ka (k1) * mka(i,L)
        fhka(i)  = alphah_ka (k1) * (1.d0 - hka(i,L)) -
     X              betah_ka (k1) * hka(i,L)
        fmk2(i)  = alpham_k2 (k1) * (1.d0 - mk2(i,L)) -
     X              betam_k2 (k1) * mk2(i,L)
        fhk2(i)  = alphah_k2 (k1) * (1.d0 - hk2(i,L)) -
     X              betah_k2 (k1) * hk2(i,L)
        fmkm(i)  = alpham_km (k1) * (1.d0 - mkm(i,L)) -
     X              betam_km (k1) * mkm(i,L)
        fmkc(i)  = alpham_kc (k1) * (1.d0 - mkc(i,L)) -
     X              betam_kc (k1) * mkc(i,L)
        fmcat(i) = alpham_cat(k1) * (1.d0 - mcat(i,L)) -
     X              betam_cat(k1) * mcat(i,L)
        fhcat(i) = alphah_cat(k1) * (1.d0 - hcat(i,L)) -
     X              betah_cat(k1) * hcat(i,L)
        fmcaL(i) = alpham_caL(k1) * (1.d0 - mcaL(i,L)) -
     X              betam_caL(k1) * mcaL(i,L)
        fmar(i)  = alpham_ar (k1) * (1.d0 - mar(i,L)) -
     X              betam_ar (k1) * mar(i,L)

       dfmnaf_dv(i) = dalpham_naf(k0) * (1.d0 - mnaf(i,L)) -
     X                  dbetam_naf(k0) * mnaf(i,L)
       dfmnap_dv(i) = dalpham_naf(k2) * (1.d0 - mnap(i,L)) -
     X                  dbetam_naf(k2) * mnap(i,L)
       dfhnaf_dv(i) = dalphah_naf(k1) * (1.d0 - hnaf(i,L)) -
     X                  dbetah_naf(k1) * hnaf(i,L)
       dfmkdr_dv(i) = dalpham_kdr(k1) * (1.d0 - mkdr(i,L)) -
     X                  dbetam_kdr(k1) * mkdr(i,L)
       dfmka_dv(i)  = dalpham_ka(k1) * (1.d0 - mka(i,L)) -
     X                  dbetam_ka(k1) * mka(i,L)
       dfhka_dv(i)  = dalphah_ka(k1) * (1.d0 - hka(i,L)) -
     X                  dbetah_ka(k1) * hka(i,L)
       dfmk2_dv(i)  = dalpham_k2(k1) * (1.d0 - mk2(i,L)) -
     X                  dbetam_k2(k1) * mk2(i,L)
       dfhk2_dv(i)  = dalphah_k2(k1) * (1.d0 - hk2(i,L)) -
     X                  dbetah_k2(k1) * hk2(i,L)
       dfmkm_dv(i)  = dalpham_km(k1) * (1.d0 - mkm(i,L)) -
     X                  dbetam_km(k1) * mkm(i,L)
       dfmkc_dv(i)  = dalpham_kc(k1) * (1.d0 - mkc(i,L)) -
     X                  dbetam_kc(k1) * mkc(i,L)
       dfmcat_dv(i) = dalpham_cat(k1) * (1.d0 - mcat(i,L)) -
     X                  dbetam_cat(k1) * mcat(i,L)
       dfhcat_dv(i) = dalphah_cat(k1) * (1.d0 - hcat(i,L)) -
     X                  dbetah_cat(k1) * hcat(i,L)
       dfmcaL_dv(i) = dalpham_caL(k1) * (1.d0 - mcaL(i,L)) -
     X                  dbetam_caL(k1) * mcaL(i,L)
       dfmar_dv(i)  = dalpham_ar(k1) * (1.d0 - mar(i,L)) -
     X                  dbetam_ar(k1) * mar(i,L)

       dfmnaf_dmnaf(i) =  - alpham_naf(k0) - betam_naf(k0)
       dfmnap_dmnap(i) =  - alpham_naf(k2) - betam_naf(k2)
       dfhnaf_dhnaf(i) =  - alphah_naf(k1) - betah_naf(k1)
       dfmkdr_dmkdr(i) =  - alpham_kdr(k1) - betam_kdr(k1)
       dfmka_dmka(i)  =   - alpham_ka (k1) - betam_ka (k1)
       dfhka_dhka(i)  =   - alphah_ka (k1) - betah_ka (k1)
       dfmk2_dmk2(i)  =   - alpham_k2 (k1) - betam_k2 (k1)
       dfhk2_dhk2(i)  =   - alphah_k2 (k1) - betah_k2 (k1)
       dfmkm_dmkm(i)  =   - alpham_km (k1) - betam_km (k1)
       dfmkc_dmkc(i)  =   - alpham_kc (k1) - betam_kc (k1)
       dfmcat_dmcat(i) =  - alpham_cat(k1) - betam_cat(k1)
       dfhcat_dhcat(i) =  - alphah_cat(k1) - betah_cat(k1)
       dfmcaL_dmcaL(i) =  - alpham_caL(k1) - betam_caL(k1)
       dfmar_dmar(i)  =   - alpham_ar (k1) - betam_ar (k1)

          end do

       dt2 = 0.5d0 * dt * dt

        do i = 1, numcomp
          v(i,L) = v(i,L) + dt * fv(i)
           do j = 1, numcomp
        v(i,L) = v(i,L) + dt2 * dfv_dv(i,j) * fv(j)
           end do
        v(i,L) = v(i,L) + dt2 * ( dfv_dchi(i) * fchi(i)
     X          + dfv_dmnaf(i) * fmnaf(i)
     X          + dfv_dmnap(i) * fmnap(i)
     X          + dfv_dhnaf(i) * fhnaf(i)
     X          + dfv_dmkdr(i) * fmkdr(i)
     X          + dfv_dmka(i)  * fmka(i)
     X          + dfv_dhka(i)  * fhka(i)
     X          + dfv_dmk2(i)  * fmk2(i)
     X          + dfv_dhk2(i)  * fhk2(i)
     X          + dfv_dmkm(i)  * fmkm(i)
     X          + dfv_dmkc(i)  * fmkc(i)
     X          + dfv_dmkahp(i)* fmkahp(i)
     X          + dfv_dmcat(i)  * fmcat(i)
     X          + dfv_dhcat(i) * fhcat(i)
     X          + dfv_dmcaL(i) * fmcaL(i)
     X          + dfv_dmar(i)  * fmar(i) )

        chi(i,L) = chi(i,L) + dt * fchi(i) + dt2 *
     X   (dfchi_dchi(i) * fchi(i) + dfchi_dv(i) * fv(i))
        mnaf(i,L) = mnaf(i,L) + dt * fmnaf(i) + dt2 *
     X   (dfmnaf_dmnaf(i) * fmnaf(i) + dfmnaf_dv(i)*fv(i))
        mnap(i,L) = mnap(i,L) + dt * fmnap(i) + dt2 *
     X   (dfmnap_dmnap(i) * fmnap(i) + dfmnap_dv(i)*fv(i))
        hnaf(i,L) = hnaf(i,L) + dt * fhnaf(i) + dt2 *
     X   (dfhnaf_dhnaf(i) * fhnaf(i) + dfhnaf_dv(i)*fv(i))
        mkdr(i,L) = mkdr(i,L) + dt * fmkdr(i) + dt2 *
     X   (dfmkdr_dmkdr(i) * fmkdr(i) + dfmkdr_dv(i)*fv(i))
        mka(i,L) =  mka(i,L) + dt * fmka(i) + dt2 *
     X   (dfmka_dmka(i) * fmka(i) + dfmka_dv(i) * fv(i))
        hka(i,L) =  hka(i,L) + dt * fhka(i) + dt2 *
     X   (dfhka_dhka(i) * fhka(i) + dfhka_dv(i) * fv(i))
        mk2(i,L) =  mk2(i,L) + dt * fmk2(i) + dt2 *
     X   (dfmk2_dmk2(i) * fmk2(i) + dfmk2_dv(i) * fv(i))
        hk2(i,L) =  hk2(i,L) + dt * fhk2(i) + dt2 *
     X   (dfhk2_dhk2(i) * fhk2(i) + dfhk2_dv(i) * fv(i))
        mkm(i,L) =  mkm(i,L) + dt * fmkm(i) + dt2 *
     X   (dfmkm_dmkm(i) * fmkm(i) + dfmkm_dv(i) * fv(i))
        mkc(i,L) =  mkc(i,L) + dt * fmkc(i) + dt2 *
     X   (dfmkc_dmkc(i) * fmkc(i) + dfmkc_dv(i) * fv(i))
        mkahp(i,L) = mkahp(i,L) + dt * fmkahp(i) + dt2 *
     X (dfmkahp_dmkahp(i)*fmkahp(i) + dfmkahp_dchi(i)*fchi(i))
        mcat(i,L) =  mcat(i,L) + dt * fmcat(i) + dt2 *
     X   (dfmcat_dmcat(i) * fmcat(i) + dfmcat_dv(i) * fv(i))
        hcat(i,L) =  hcat(i,L) + dt * fhcat(i) + dt2 *
     X   (dfhcat_dhcat(i) * fhcat(i) + dfhcat_dv(i) * fv(i))
        mcaL(i,L) =  mcaL(i,L) + dt * fmcaL(i) + dt2 *
     X   (dfmcaL_dmcaL(i) * fmcaL(i) + dfmcaL_dv(i) * fv(i))
        mar(i,L) =   mar(i,L) + dt * fmar(i) + dt2 *
     X   (dfmar_dmar(i) * fmar(i) + dfmar_dv(i) * fv(i))
c            endif
         end do

! Add membrane currents into membcurr for appropriate compartments
          do i = 1, 6
           j = level(i)
           membcurr(j) = membcurr(j) + fv(i) * c(i)
          end do
          do i = 13, 17
           j = level(i)
           membcurr(j) = membcurr(j) + fv(i) * c(i)
          end do
          do i = 24, 28
           j = level(i)
           membcurr(j) = membcurr(j) + fv(i) * c(i)
          end do
          do i = 35, 44
           j = level(i)
           membcurr(j) = membcurr(j) + fv(i) * c(i)
          end do

           end do ! do L

         field_1mm = 0.d0
         field_2mm = 0.d0

         do i = 1, 14
          field_1mm = field_1mm + membcurr(i) / dabs(1000.d0 - depth(i))
          field_2mm = field_2mm + membcurr(i) / dabs(2000.d0 - depth(i))
         end do

4000          END

        SUBROUTINE nontuftRSMAJ
C BRANCHED ACTIVE DENDRITES
     X             (GL,GAM,GKDR,GKA,GKC,GKAHP,GK2,GKM,
     X              GCAT,GCAL,GNAF,GNAP,GAR,
     X    CAFOR,JACOB,C,BETCHI,NEIGH,NNUM,depth,level)
c Conductances: leak gL, coupling g, delayed rectifier gKDR, A gKA,
c C gKC, AHP gKAHP, K2 gK2, M gKM, low thresh Ca gCAT, high thresh
c gCAL, fast Na gNAF, persistent Na gNAP, h or anom. rectif. gAR.
c Note VAR = equil. potential for anomalous rectifier.
c Soma = comp. 1; 10 dendrites each with 13 compartments, 6-comp. axon
c Drop "glc"-like terms, just using "gl"-like
c CAFOR corresponds to "phi" in Traub et al., 1994
c Consistent set of units: nF, mV, ms, nA, microS

        integer, parameter:: numcomp = 50

        REAL*8 C(numcomp),GL(numcomp),GAM(0:numcomp,0:numcomp)
        REAL*8 GNAF(numcomp),GCAT(numcomp)
        REAL*8 GKDR(numcomp),GKA(numcomp),GKC(numcomp)
        REAL*8 GKAHP(numcomp),GCAL(numcomp)
        REAL*8 GK2(numcomp),GKM(numcomp),GNAP(numcomp),GAR(numcomp)
        REAL*8 JACOB(numcomp,numcomp),RI_SD,RI_AXON,RM_SD,RM_AXON
        INTEGER LEVEL(numcomp)
        REAL*8 GNAF_DENS(0:14), GCAT_DENS(0:14), GKDR_DENS(0:14)
        REAL*8 GKA_DENS(0:14), GKC_DENS(0:14), GKAHP_DENS(0:14)
        REAL*8 GCAL_DENS(0:14), GK2_DENS(0:14), GKM_DENS(0:14)
        REAL*8 GNAP_DENS(0:14), GAR_DENS(0:14)
        REAL*8 RES, RINPUT, CDENS
        REAL*8 RSOMA, PI, BETCHI(numcomp), CAFOR(numcomp)
        REAL*8 RAD(numcomp),LEN(numcomp),GAM1,GAM2,ELEN(numcomp)
        REAL*8 RIN, D(numcomp), AREA(numcomp), RI, Z
        INTEGER NEIGH(numcomp, 7), NNUM(numcomp)
C FOR ESTABLISHING TOPOLOGY OF COMPARTMENTS
        real*8 depth(14) ! in microns, subscript refers to level

        depth(1) = 2200.d0
        depth(2) = 2245.d0
        depth(3) = 2290.d0
        depth(4) = 2335.d0
        depth(5) = 2175.d0
        depth(6) = 2125.d0
        depth(7) = 2075.d0
        depth(8) = 2025.d0
        depth(9) = 1975.d0
        depth(10) = 1925.d0
        depth(11) = 1875.d0
        depth(12) = 1825.d0
        depth(13) = 1775.d0
        depth(14) = 1725.d0

        RI_SD = 250.d0
        RM_SD = 50000.d0
        RI_AXON = 100.d0
        RM_AXON = 1000.d0
        CDENS = 0.9d0

        PI = 3.14159d0

        gnaf_dens =  5.d0
c       gnaf_dens = 10.d0
c       gnaf_dens(0) = 450.d0
        gnaf_dens(0) = 175.d0
c       gnaf_dens(1) = 200.d0
        gnaf_dens(1) = 175.d0
        gnaf_dens(2) =  75.d0
        gnaf_dens(5) = 150.d0
        gnaf_dens(6) =  75.d0

        gkdr_dens = 0.d0
        gkdr_dens(0) = 450.d0
        gkdr_dens(1) = 170.d0
        gkdr_dens(2) =  75.d0
        gkdr_dens(5) = 120.d0
        gkdr_dens(6) =  75.d0

        do i = 1, 14
          gnap_dens(i) = 0.0040d0 * gnaf_dens(i)
        end do

        do i = 1, 14
          gcat_dens(i) = 0.1d0
        end do

        do i = 1, 9
          gcaL_dens(i) = 0.20d0
        end do
        do i = 10, 14
          gcaL_dens(i) = 2.0d0
        end do

        gka_dens    = 4.d0
        gka_dens(1) = 35.d0
        gka_dens(5) = 35.d0
        do i = 1, 14
          gka_dens(i) = 3.4d0 * gka_dens(i)
        end do

        gkc_dens = 0.00d0
         gkc_dens(1) =  7.50d0
         gkc_dens(2) =  7.50d0
         gkc_dens(5) =  7.50d0
         gkc_dens(6) =  7.50d0

        do i = 1, 14
c        gkm_dens(i) = 1.4d0 * 1.50d0
         gkm_dens(i) = 2.8d0 * 1.50d0
        end do

        gk2_dens    = 0.1d0

        do i = 1, 14
c        gkahp_dens(i) = 0.100d0
         gkahp_dens(i) = 0.200d0
        end do

        do i = 1, 14
         gar_dens(i) = 0.25d0
        end do

c        if (thisno.eq.0) then
c       WRITE   (6,9988)
9988    FORMAT(2X,'I',4X,'NADENS',' CADENS(L)',' KDRDEN',' KAHPDE',
     X     ' KCDENS',' KADENS')
        DO 9989, I = 0, 14
c         WRITE (6,9990) I, gnaf_dens(i), gcaL_dens(i), gkdr_dens(i),
c    X  gkahp_dens(i), gkc_dens(i), gka_dens(i)
9990    FORMAT(2X,I2,2X,F6.2,1X,F6.2,1X,F6.2,1X,F6.2,1X,F6.2,1X,F6.2)
9989    CONTINUE
c         endif


        level(1) = 1
        do i = 2, 12
         level(i) = 2
        end do
        do i = 13, 23
           level(i) = 3
        end do
        do i = 24, 34
           level(i) = 4
        end do
        level(35) = 5
        level(36) = 6
        level(37) = 7
        level(38) = 8
        level(39) = 9
        level(40) = 10
        level(41) = 11
        level(42) = 12
        level(43) = 13
        level(44) = 14

        do i =  45, 50
         level(i) = 0
        end do

c connectivity of axon
        nnum( 45) = 2
        nnum( 46) = 3
        nnum( 47) = 3
        nnum( 49) = 3
        nnum( 48) = 1
        nnum( 50) = 1
         neigh(45,1) =  1
         neigh(45,2) = 46
         neigh(46,1) = 45
         neigh(46,2) = 47
         neigh(46,3) = 49
         neigh(47,1) = 46
         neigh(47,2) = 48
         neigh(47,3) = 49
         neigh(49,1) = 46
         neigh(49,2) = 47
         neigh(49,3) = 50
         neigh(48,1) = 47
         neigh(50,1) = 49

c connectivity of SD part
          nnum(1) = 7
          neigh(1,1) = 45
          neigh(1,2) =  2
          neigh(1,3) =  3
          neigh(1,4) =  4
          neigh(1,5) =  5
          neigh(1,6) =  6
          neigh(1,7) = 35

          do i = 2, 6
           nnum(i) = 2
           neigh(i,1) = 1
           neigh(i,2) = i + 11
          end do

          do i = 13, 17
            nnum(i) = 2
            neigh(i,1) = i - 11
            neigh(i,2) = i + 11
          end do

          do i = 24, 28
            nnum(i) = 1
            neigh(i,1) = i - 11
          end do

          do i =  7, 12
            nnum(i) = 2
      if ((i.eq.7).or.(i.eq.12)) neigh(i,1) = 35
      if ((i.eq.8).or.(i.eq.11)) neigh(i,1) = 36
      if ((i.eq.9).or.(i.eq.10)) neigh(i,1) = 37
            neigh(i,2) = i + 11
          end do

          do i = 18, 23
            nnum(i) = 2
            neigh(i,1) = i - 11
            neigh(i,2) = i + 11
          end do

          do i = 29, 34
            nnum(i) = 1
            neigh(i,1) = i - 11
          end do

          nnum(35) = 4
          neigh(35,1) = 1
          neigh(35,2) = 36
          neigh(35,3) =  7
          neigh(35,4) = 12

          nnum(36) = 4
          neigh(36,1) = 35
          neigh(36,2) = 37
          neigh(36,3) =  8
          neigh(36,4) = 11

          nnum(37) = 4
          neigh(37,1) = 36
          neigh(37,2) = 38
          neigh(37,3) =  9
          neigh(37,4) = 10

          nnum(38) = 2
          neigh(38,1) = 37
          neigh(38,2) = 39

          nnum(39) = 2
          neigh(39,1) = 38
          neigh(39,2) = 40

          nnum(40) = 2
          neigh(40,1) = 39
          neigh(40,2) = 41

          nnum(41) = 2
          neigh(41,1) = 40
          neigh(41,2) = 42

          nnum(42) = 2
          neigh(42,1) = 41
          neigh(42,2) = 43

          nnum(43) = 2
          neigh(43,1) = 42
          neigh(43,2) = 44

          nnum(44) = 1
          neigh(44,1) = 43

c           if (thisno.eq.0) then
         DO 332, I = 1, numcomp
c          WRITE(6,3330) I, NEIGH(I,1),NEIGH(I,2),NEIGH(I,3),NEIGH(I,4),
c    X NEIGH(I,5),NEIGH(I,6),NEIGH(I,7)
3330     FORMAT(2X, 8I5)
332      CONTINUE
c            endif

          DO 858, I = 1, numcomp
           DO 858, J = 1, NNUM(I)
            K = NEIGH(I,J)
            IT = 0
            DO 859, L = 1, NNUM(K)
             IF (NEIGH(K,L).EQ.I) IT = 1
859         CONTINUE
             IF (IT.EQ.0) THEN
c             WRITE(6,8591) I, K
8591          FORMAT(' ASYMMETRY IN NEIGH MATRIX ',I4,I4)
              STOP
             ENDIF
858       CONTINUE

c length and radius of axonal compartments
c Note shortened "initial segment"
          len(45) = 25.d0
          do i = 46, 50
            len(i) = 50.d0
          end do
          rad( 45) = 0.90d0
          rad( 46) = 0.7d0
          do i = 47, 50
           rad(i) = 0.5d0
          end do

c  length and radius of SD compartments
          len(1) = 20.d0
          rad(1) =  8.d0

          do i = 2, 34
           len(i) = 60.d0
          end do

          do i = 35, 44
           len(i) = 50.d0
          end do

          do i = 2, 6
            rad(i) = 0.85d0
          end do
          do i = 13, 17
            rad(i) = 0.85d0
          end do
          do i = 24, 28
            rad(i) = 0.85d0
          end do

          do i = 7, 12
            rad(i) = 0.62d0
          end do
          do i = 18, 23
            rad(i) = 0.62d0
          end do
          do i = 29, 34
            rad(i) = 0.62d0
          end do

          rad(35) = 1.5d0
          rad(36) = 1.4d0
          rad(37) = 1.3d0
          rad(38) = 1.2d0
          rad(39) = 1.1d0
          rad(40) = 1.0d0
          rad(41) = 0.9d0
          rad(42) = 0.8d0
          rad(43) = 0.7d0
          rad(44) = 0.6d0


c            if (thisno.eq.0) then
        WRITE(6,919)
919     FORMAT('COMPART.',' LEVEL ',' RADIUS ',' LENGTH(MU)')
c       DO 920, I = 1, numcomp
c920      WRITE(6,921) I, LEVEL(I), RAD(I), LEN(I)
921     FORMAT(I3,5X,I2,3X,F6.2,1X,F6.1,2X,F4.3)
c            endif

        DO 120, I = 1, numcomp
          AREA(I) = 2.d0 * PI * RAD(I) * LEN(I)
      if((i.gt.1).and.(i.le.44)) area(i) = 2.d0 * area(i)
C    CORRECTION FOR CONTRIBUTION OF SPINES TO AREA
          K = LEVEL(I)
          C(I) = CDENS * AREA(I) * (1.D-8)

           if (k.ge.1) then
          GL(I) = (1.D-2) * AREA(I) / RM_SD
           else
          GL(I) = (1.D-2) * AREA(I) / RM_AXON
           endif

          GNAF(I) = GNAF_DENS(K) * AREA(I) * (1.D-5)
          GNAP(I) = GNAP_DENS(K) * AREA(I) * (1.D-5)
          GCAT(I) = GCAT_DENS(K) * AREA(I) * (1.D-5)
          GKDR(I) = GKDR_DENS(K) * AREA(I) * (1.D-5)
          GKA(I) = GKA_DENS(K) * AREA(I) * (1.D-5)
          GKC(I) = GKC_DENS(K) * AREA(I) * (1.D-5)
          GKAHP(I) = GKAHP_DENS(K) * AREA(I) * (1.D-5)
          GCAL(I) = GCAL_DENS(K) * AREA(I) * (1.D-5)
          GK2(I) = GK2_DENS(K) * AREA(I) * (1.D-5)
          GKM(I) = GKM_DENS(K) * AREA(I) * (1.D-5)
          GAR(I) = GAR_DENS(K) * AREA(I) * (1.D-5)
c above conductances should be in microS
120           continue

         Z = 0.d0
         DO 1019, I = 2, 44
           Z = Z + AREA(I)
1019     CONTINUE
c             if (thisno.eq.1) then
c        WRITE(6,1020) Z
c              endif
1020     FORMAT(2X,' TOTAL DENDRITIC AREA ',F7.0)

        DO 140, I = 1, numcomp
        DO 140, K = 1, NNUM(I)
         J = NEIGH(I,K)
           if (level(i).eq.0) then
               RI = RI_AXON
           else
               RI = RI_SD
           endif
         GAM1 =100.d0 * PI * RAD(I) * RAD(I) / ( RI * LEN(I) )

           if (level(j).eq.0) then
               RI = RI_AXON
           else
               RI = RI_SD
           endif
         GAM2 =100.d0 * PI * RAD(J) * RAD(J) / ( RI * LEN(J) )

         GAM(I,J) = 2.d0/( (1.d0/GAM1) + (1.d0/GAM2) )
140     CONTINUE
c gam computed in microS

        DO 299, I = 1, numcomp
299       BETCHI(I) = .05d0
        BETCHI( 1) =  .01d0

        DO 300, I = 1, numcomp
300     D(I) = 4.D-4
        DO 301, I = 1, numcomp
         IF (LEVEL(I).EQ.1) D(I) = 4.D-3
301     CONTINUE


       DO 160, I = 1, numcomp
160     CAFOR(I) = 5200.d0 / (AREA(I) * D(I))
C     NOTE CORRECTION

        do 200, i = 1, numcomp
200     C(I) = 1000.d0 * C(I)
C     TO GO FROM MICROF TO NF.

      DO 909, I = 1, numcomp
       JACOB(I,I) = - GL(I)
      DO 909, J = 1, NNUM(I)
         K = NEIGH(I,J)
         IF (I.EQ.K) THEN
c            WRITE(6,510) I
510          FORMAT(' UNEXPECTED SYMMETRY IN NEIGH ',I4)
         ENDIF
         JACOB(I,K) = GAM(I,K)
         JACOB(I,I) = JACOB(I,I) - GAM(I,K)
909   CONTINUE

c 15 Jan. 2001: make correction for c(i)
          do i = 1, numcomp
          do j = 1, numcomp
             jacob(i,j) = jacob(i,j) / c(i)
          end do
          end do

c          if (thisno.eq.1) then
       DO 500, I = 1, numcomp
c       WRITE (6,501) I,C(I)
501     FORMAT(1X,I3,' C(I) = ',F7.4)
500     CONTINUE
c               endif

        END

C  SETS UP TABLES FOR RATE FUNCTIONS
       SUBROUTINE nontuftRS_SETUP
     X   (alpham_naf, betam_naf, dalpham_naf, dbetam_naf,
     X    alphah_naf, betah_naf, dalphah_naf, dbetah_naf,
     X    alpham_kdr, betam_kdr, dalpham_kdr, dbetam_kdr,
     X    alpham_ka , betam_ka , dalpham_ka , dbetam_ka ,
     X    alphah_ka , betah_ka , dalphah_ka , dbetah_ka ,
     X    alpham_k2 , betam_k2 , dalpham_k2 , dbetam_k2 ,
     X    alphah_k2 , betah_k2 , dalphah_k2 , dbetah_k2 ,
     X    alpham_km , betam_km , dalpham_km , dbetam_km ,
     X    alpham_kc , betam_kc , dalpham_kc , dbetam_kc ,
     X    alpham_cat, betam_cat, dalpham_cat, dbetam_cat,
     X    alphah_cat, betah_cat, dalphah_cat, dbetah_cat,
     X    alpham_caL, betam_caL, dalpham_caL, dbetam_caL,
     X    alpham_ar , betam_ar , dalpham_ar , dbetam_ar)
      INTEGER I,J,K
      real*8 minf, hinf, taum, tauh, V, Z, shift_hnaf,
     X  shift_mkdr,
     X alpham_naf(0:640),betam_naf(0:640),dalpham_naf(0:640),
     X   dbetam_naf(0:640),
     X alphah_naf(0:640),betah_naf(0:640),dalphah_naf(0:640),
     X   dbetah_naf(0:640),
     X alpham_kdr(0:640),betam_kdr(0:640),dalpham_kdr(0:640),
     X   dbetam_kdr(0:640),
     X alpham_ka(0:640), betam_ka(0:640),dalpham_ka(0:640) ,
     X   dbetam_ka(0:640),
     X alphah_ka(0:640), betah_ka(0:640), dalphah_ka(0:640),
     X   dbetah_ka(0:640),
     X alpham_k2(0:640), betam_k2(0:640), dalpham_k2(0:640),
     X   dbetam_k2(0:640),
     X alphah_k2(0:640), betah_k2(0:640), dalphah_k2(0:640),
     X   dbetah_k2(0:640),
     X alpham_km(0:640), betam_km(0:640), dalpham_km(0:640),
     X   dbetam_km(0:640),
     X alpham_kc(0:640), betam_kc(0:640), dalpham_kc(0:640),
     X   dbetam_kc(0:640),
     X alpham_cat(0:640),betam_cat(0:640),dalpham_cat(0:640),
     X   dbetam_cat(0:640),
     X alphah_cat(0:640),betah_cat(0:640),dalphah_cat(0:640),
     X   dbetah_cat(0:640),
     X alpham_caL(0:640),betam_caL(0:640),dalpham_caL(0:640),
     X   dbetam_caL(0:640),
     X alpham_ar(0:640), betam_ar(0:640), dalpham_ar(0:640),
     X   dbetam_ar(0:640)
C FOR VOLTAGE, RANGE IS -120 TO +40 MV (absol.), 0.25 MV RESOLUTION


       DO 1, I = 0, 640
          V = dble(I)
          V = (V / 4.d0) - 120.d0

c gNa
           minf = 1.d0/(1.d0 + dexp((-V-38.d0)/10.d0))
           if (v.le.-30.d0) then
            taum = .025d0 + .14d0*dexp((v+30.d0)/10.d0)
           else
            taum = .02d0 + .145d0*dexp((-v-30.d0)/10.d0)
           endif
c from principal c. data, Martina & Jonas 1997, tau x 0.5
c Note that minf about the same for interneuron & princ. cell.
           alpham_naf(i) = minf / taum
           betam_naf(i) = 1.d0/taum - alpham_naf(i)

            shift_hnaf =  0.d0
        hinf = 1.d0/(1.d0 +
     x     dexp((v + shift_hnaf + 62.9d0)/10.7d0))
        tauh = 0.15d0 + 1.15d0/(1.d0+dexp((v+37.d0)/15.d0))
c from princ. cell data, Martina & Jonas 1997, tau x 0.5
            alphah_naf(i) = hinf / tauh
            betah_naf(i) = 1.d0/tauh - alphah_naf(i)

          shift_mkdr = 0.d0
c delayed rectifier, non-inactivating
       minf = 1.d0/(1.d0+dexp((-v-shift_mkdr-29.5d0)/10.0d0))
            if (v.le.-10.d0) then
             taum = .25d0 + 4.35d0*dexp((v+10.d0)/10.d0)
            else
             taum = .25d0 + 4.35d0*dexp((-v-10.d0)/10.d0)
            endif
              alpham_kdr(i) = minf / taum
              betam_kdr(i) = 1.d0 /taum - alpham_kdr(i)
c from Martina, Schultz et al., 1998. See espec. Table 1.

c A current: Huguenard & McCormick 1992, J Neurophysiol (TCR)
            minf = 1.d0/(1.d0 + dexp((-v-60.d0)/8.5d0))
            hinf = 1.d0/(1.d0 + dexp((v+78.d0)/6.d0))
        taum = .185d0 + .5d0/(dexp((v+35.8d0)/19.7d0) +
     x                            dexp((-v-79.7d0)/12.7d0))
        if (v.le.-63.d0) then
         tauh = .5d0/(dexp((v+46.d0)/5.d0) +
     x                  dexp((-v-238.d0)/37.5d0))
        else
         tauh = 9.5d0
        endif
           alpham_ka(i) = minf/taum
           betam_ka(i) = 1.d0 / taum - alpham_ka(i)
           alphah_ka(i) = hinf / tauh
           betah_ka(i) = 1.d0 / tauh - alphah_ka(i)

c h-current (anomalous rectifier), Huguenard & McCormick, 1992
           minf = 1.d0/(1.d0 + dexp((v+75.d0)/5.5d0))
           taum = 1.d0/(dexp(-14.6d0 -0.086d0*v) +
     x                   dexp(-1.87 + 0.07d0*v))
           alpham_ar(i) = minf / taum
           betam_ar(i) = 1.d0 / taum - alpham_ar(i)

c K2 K-current, McCormick & Huguenard
             minf = 1.d0/(1.d0 + dexp((-v-10.d0)/17.d0))
             hinf = 1.d0/(1.d0 + dexp((v+58.d0)/10.6d0))
            taum = 4.95d0 + 0.5d0/(dexp((v-81.d0)/25.6d0) +
     x                  dexp((-v-132.d0)/18.d0))
            tauh = 60.d0 + 0.5d0/(dexp((v-1.33d0)/200.d0) +
     x                  dexp((-v-130.d0)/7.1d0))
             alpham_k2(i) = minf / taum
             betam_k2(i) = 1.d0/taum - alpham_k2(i)
             alphah_k2(i) = hinf / tauh
             betah_k2(i) = 1.d0 / tauh - alphah_k2(i)

c voltage part of C-current, using 1994 kinetics, shift 60 mV
              if (v.le.-10.d0) then
       alpham_kc(i) = (2.d0/37.95d0)*dexp((v+50.d0)/11.d0 -
     x                                     (v+53.5)/27.d0)
       betam_kc(i) = 2.d0*dexp((-v-53.5d0)/27.d0)-alpham_kc(i)
               else
       alpham_kc(i) = 2.d0*dexp((-v-53.5d0)/27.d0)
       betam_kc(i) = 0.d0
               endif

c high-threshold gCa, from 1994, with 60 mV shift & no inactivn.
            alpham_cal(i) = 1.6d0/(1.d0+dexp(-.072d0*(v-5.d0)))
            betam_cal(i) = 0.1d0 * ((v+8.9d0)/5.d0) /
     x          (dexp((v+8.9d0)/5.d0) - 1.d0)

c M-current, from plast.f, with 60 mV shift
        alpham_km(i) = .02d0/(1.d0+dexp((-v-20.d0)/5.d0))
        betam_km(i) = .01d0 * dexp((-v-43.d0)/18.d0)

c T-current, from Destexhe, Neubig et al., 1998
         minf = 1.d0/(1.d0 + dexp((-v-56.d0)/6.2d0))
         hinf = 1.d0/(1.d0 + dexp((v+80.d0)/4.d0))
         taum = 0.204d0 + .333d0/(dexp((v+15.8d0)/18.2d0) +
     x                  dexp((-v-131.d0)/16.7d0))
          if (v.le.-81.d0) then
         tauh = 0.333 * dexp((v+466.d0)/66.6d0)
          else
         tauh = 9.32d0 + 0.333d0*dexp((-v-21.d0)/10.5d0)
          endif
              alpham_cat(i) = minf / taum
              betam_cat(i) = 1.d0/taum - alpham_cat(i)
              alphah_cat(i) = hinf / tauh
              betah_cat(i) = 1.d0 / tauh - alphah_cat(i)

1        CONTINUE

         do 2, i = 0, 639

      dalpham_naf(i) = (alpham_naf(i+1)-alpham_naf(i))/.25d0
      dbetam_naf(i) = (betam_naf(i+1)-betam_naf(i))/.25d0
      dalphah_naf(i) = (alphah_naf(i+1)-alphah_naf(i))/.25d0
      dbetah_naf(i) = (betah_naf(i+1)-betah_naf(i))/.25d0
      dalpham_kdr(i) = (alpham_kdr(i+1)-alpham_kdr(i))/.25d0
      dbetam_kdr(i) = (betam_kdr(i+1)-betam_kdr(i))/.25d0
      dalpham_ka(i) = (alpham_ka(i+1)-alpham_ka(i))/.25d0
      dbetam_ka(i) = (betam_ka(i+1)-betam_ka(i))/.25d0
      dalphah_ka(i) = (alphah_ka(i+1)-alphah_ka(i))/.25d0
      dbetah_ka(i) = (betah_ka(i+1)-betah_ka(i))/.25d0
      dalpham_k2(i) = (alpham_k2(i+1)-alpham_k2(i))/.25d0
      dbetam_k2(i) = (betam_k2(i+1)-betam_k2(i))/.25d0
      dalphah_k2(i) = (alphah_k2(i+1)-alphah_k2(i))/.25d0
      dbetah_k2(i) = (betah_k2(i+1)-betah_k2(i))/.25d0
      dalpham_km(i) = (alpham_km(i+1)-alpham_km(i))/.25d0
      dbetam_km(i) = (betam_km(i+1)-betam_km(i))/.25d0
      dalpham_kc(i) = (alpham_kc(i+1)-alpham_kc(i))/.25d0
      dbetam_kc(i) = (betam_kc(i+1)-betam_kc(i))/.25d0
      dalpham_cat(i) = (alpham_cat(i+1)-alpham_cat(i))/.25d0
      dbetam_cat(i) = (betam_cat(i+1)-betam_cat(i))/.25d0
      dalphah_cat(i) = (alphah_cat(i+1)-alphah_cat(i))/.25d0
      dbetah_cat(i) = (betah_cat(i+1)-betah_cat(i))/.25d0
      dalpham_caL(i) = (alpham_cal(i+1)-alpham_cal(i))/.25d0
      dbetam_caL(i) = (betam_cal(i+1)-betam_cal(i))/.25d0
      dalpham_ar(i) = (alpham_ar(i+1)-alpham_ar(i))/.25d0
      dbetam_ar(i) = (betam_ar(i+1)-betam_ar(i))/.25d0
2      CONTINUE
       END

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