Dentate gyrus (Morgan et al. 2007, 2008, Santhakumar et al. 2005, Dyhrfjeld-Johnsen et al. 2007)

 Download zip file   Auto-launch 
Help downloading and running models
Accession:124513
This model was implemented by Rob Morgan in the Soltesz lab at UC Irvine. It is a scaleable model of the rat dentate gyrus including four cell types. This model runs in serial (on a single processor) and has been published at the size of 50,000 granule cells (with proportional numbers of the other cells).
References:
1 . Santhakumar V, Aradi I, Soltesz I (2005) Role of mossy fiber sprouting and mossy cell loss in hyperexcitability: a network model of the dentate gyrus incorporating cell types and axonal topography. J Neurophysiol 93:437-53 [PubMed]
2 . Dyhrfjeld-Johnsen J, Santhakumar V, Morgan RJ, Huerta R, Tsimring L, Soltesz I (2007) Topological determinants of epileptogenesis in large-scale structural and functional models of the dentate gyrus derived from experimental data. J Neurophysiol 97:1566-87 [PubMed]
3 . Morgan RJ, Soltesz I (2008) Nonrandom connectivity of the epileptic dentate gyrus predicts a major role for neuronal hubs in seizures. Proc Natl Acad Sci U S A 105:6179-84 [PubMed]
4 . Morgan RJ, Santhakumar V, Soltesz I (2007) Modeling the dentate gyrus. Prog Brain Res 163:639-58 [PubMed]
Model Information (Click on a link to find other models with that property)
Model Type: Realistic Network;
Brain Region(s)/Organism: Dentate gyrus;
Cell Type(s): Dentate gyrus granule cell; Dentate gyrus mossy cell; Dentate gyrus basket cell; Dentate gyrus hilar cell;
Channel(s):
Gap Junctions:
Receptor(s):
Gene(s):
Transmitter(s):
Simulation Environment: NEURON;
Model Concept(s): Epilepsy;
Implementer(s): Bezaire, Marianne [mariannejcase at gmail.com]; Morgan, Robert [polomav at gmail.com];
Search NeuronDB for information about:  Dentate gyrus granule cell;
Files displayed below are from the implementation
/
dentate_gyrus
500net
README.html
bgka.mod *
CaBK.mod
ccanl.mod *
Gfluct2.mod
gskch.mod *
hyperde3.mod *
ichan2.mod *
inhsyn.mod
LcaMig.mod *
nca.mod
ppsyn.mod
tca.mod *
50knet.hoc
bcdist.hoc
bcell.bcell
bcell.gcell
bcell.hcell *
bcell.mcell
gcdist.hoc
gcell.bcell
gcell.gcell
gcell.hcell
gcell.mcell
hcdist.hoc
hcell.bcell
hcell.gcell
hcell.hcell *
hcell.mcell
mcdist.hoc
mcell.bcell
mcell.gcell
mcell.hcell
mcell.mcell
mosinit.hoc
parameters.dat
pbc.hoc
pgc.hoc
phc.hoc
pmc.hoc
run50knet.bash
screenshot.jpg
                            
TITLE T-calcium channel From Migliore CA3
: T-type calcium channel


UNITS {
	(mA) = (milliamp)
	(mV) = (millivolt)

	FARADAY = 96520 (coul)
	R = 8.3134 (joule/degC)
	KTOMV = .0853 (mV/degC)
}

PARAMETER {
	v (mV)
	celsius = 6.3	(degC)
	gcatbar=.003 (mho/cm2)
	cai (mM)
	cao (mM)
}


NEURON {
	SUFFIX cat
	USEION tca READ etca WRITE itca VALENCE 2
	USEION ca READ cai, cao VALENCE 2
        RANGE gcatbar,cai, itca, etca
}

STATE {
	m h 
}

ASSIGNED {
	itca (mA/cm2)
        gcat (mho/cm2)
	etca (mV)
}

INITIAL {
      m = minf(v)
      h = hinf(v)
	VERBATIM
	cai=_ion_cai;
	ENDVERBATIM
}

BREAKPOINT {
	SOLVE states METHOD cnexp
	gcat = gcatbar*m*m*h
	itca = gcat*ghk(v,cai,cao)

}

DERIVATIVE states {	: exact when v held constant
	m' = (minf(v) - m)/m_tau(v)
	h' = (hinf(v) - h)/h_tau(v)
}


FUNCTION ghk(v(mV), ci(mM), co(mM)) (mV) {
        LOCAL nu,f

        f = KTF(celsius)/2
        nu = v/f
        ghk=-f*(1. - (ci/co)*exp(nu))*efun(nu)
}

FUNCTION KTF(celsius (DegC)) (mV) {
        KTF = ((25./293.15)*(celsius + 273.15))
}


FUNCTION efun(z) {
	if (fabs(z) < 1e-4) {
		efun = 1 - z/2
	}else{
		efun = z/(exp(z) - 1)
	}
}

FUNCTION hinf(v(mV)) {
	LOCAL a,b
	TABLE FROM -150 TO 150 WITH 200
	a = 1.e-6*exp(-v/16.26)
	b = 1/(exp((-v+29.79)/10)+1)
	hinf = a/(a+b)
}

FUNCTION minf(v(mV)) {
	LOCAL a,b
	TABLE FROM -150 TO 150 WITH 200
        
	a = 0.2*(-1.0*v+19.26)/(exp((-1.0*v+19.26)/10.0)-1.0)
	b = 0.009*exp(-v/22.03)
	minf = a/(a+b)
}

FUNCTION m_tau(v(mV)) (ms) {
	LOCAL a,b
	TABLE FROM -150 TO 150 WITH 200
	a = 0.2*(-1.0*v+19.26)/(exp((-1.0*v+19.26)/10.0)-1.0)
	b = 0.009*exp(-v/22.03)
	m_tau = 1/(a+b)
}

FUNCTION h_tau(v(mV)) (ms) {
	LOCAL a,b
        TABLE FROM -150 TO 150 WITH 200
	a = 1.e-6*exp(-v/16.26)
	b = 1/(exp((-v+29.79)/10.)+1.)
	h_tau = 1/(a+b)
}

Loading data, please wait...