Olfactory bulb microcircuits model with dual-layer inhibition (Gilra & Bhalla 2015)

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Accession:153574
A detailed network model of the dual-layer dendro-dendritic inhibitory microcircuits in the rat olfactory bulb comprising compartmental mitral, granule and PG cells developed by Aditya Gilra, Upinder S. Bhalla (2015). All cell morphologies and network connections are in NeuroML v1.8.0. PG and granule cell channels and synapses are also in NeuroML v1.8.0. Mitral cell channels and synapses are in native python.
Reference:
1 . Gilra A, Bhalla US (2015) Bulbar microcircuit model predicts connectivity and roles of interneurons in odor coding. PLoS One 10:e0098045 [PubMed]
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Model Information (Click on a link to find other models with that property)
Model Type: Realistic Network;
Brain Region(s)/Organism: Olfactory bulb;
Cell Type(s): Olfactory bulb main mitral GLU cell; Olfactory bulb main interneuron periglomerular GABA cell; Olfactory bulb main interneuron granule MC GABA cell;
Channel(s): I A; I h; I K,Ca; I Sodium; I Calcium; I Potassium;
Gap Junctions:
Receptor(s): AMPA; NMDA; Gaba;
Gene(s):
Transmitter(s): Gaba; Glutamate;
Simulation Environment: Python; MOOSE/PyMOOSE;
Model Concept(s): Sensory processing; Sensory coding; Markov-type model; Olfaction;
Implementer(s): Bhalla, Upinder S [bhalla at ncbs.res.in]; Gilra, Aditya [aditya_gilra -at- yahoo -period- com];
Search NeuronDB for information about:  Olfactory bulb main mitral GLU cell; Olfactory bulb main interneuron periglomerular GABA cell; Olfactory bulb main interneuron granule MC GABA cell; AMPA; NMDA; Gaba; I A; I h; I K,Ca; I Sodium; I Calcium; I Potassium; Gaba; Glutamate;
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olfactory-bulb-gilra-bhalla
channels
neuron_channels
CaHVA_Chan.xml
CaL_Chan.xml
CaLChannel.py
CaPool.py
CaTChannel.py
channelConstants.py
granuleDefaults.py
Ih_cb.xml
KAChannel.py
KAChannelMS.py
KCaA.dat
KCaA_PG.dat
KCaB.dat
KCaB_PG.dat
KCaChannel.py
KCaChannel_PG.py
KCaMPIChannel.py
KCaMPIChannel_PG.py
KDRChannelMS.py
kfast_k.inf *
kfast_k.tau *
kfast_n.inf *
kfast_n.tau *
KFastChannel.py
KMChannel.py
kslow_k.inf *
kslow_k.tau *
kslow_n.inf *
kslow_n.tau *
KSlowChannel.py
load_channels.py
MOOSEChannelTest.py
NaChannel.py
NaGranChannel.py
NaMitChannelMS.py
tabchannels.dat *
TCa_d.xml
                            
#!/usr/bin/env python
# -*- coding: utf-8 -*-
import sys
import math

# The PYTHONPATH should contain the location of moose.py and _moose.so
# files.  Putting ".." with the assumption that moose.py and _moose.so
# has been generated in ${MOOSE_SOURCE_DIRECTORY}/pymoose/ (as default
# pymoose build does) and this file is located in
# ${MOOSE_SOURCE_DIRECTORY}/pymoose/examples
# sys.path.append('..\..')
try:
    import moose
except ImportError:
    print "ERROR: Could not import moose. Please add the directory containing moose.py in your PYTHONPATH"
    import sys
    sys.exit(1)

from channelConstants import *

# ALL SI UNITS

VCa = 0.070 # Volts

GCa = 40*sarea # Siemens, from mit4.hoc

def calc_Ca_alpha_s(v):
    return 7.5e3/(1+math.exp((-30e-3-v)/7e-3))

def calc_Ca_beta_s(v):
    return 1.65e3/(1+math.exp((v+30e-3)/4e-3))

def calc_Ca_alpha_r(v):
    return 6.8/(1+math.exp((v+60e-3)/12e-3))

def calc_Ca_beta_r(v):
    return 60/(1+math.exp(-v-30e-3/11e-3))


class CaTChannel(moose.HHChannel):
    """Ca channel inherits from HHChannel."""
    def __init__(self, *args):
        """Setup the Ca channel with defaults"""
        moose.HHChannel.__init__(self,*args)
        self.Ek = VCa
        self.Gbar = GCa
        self.addField('ion')
        self.setField('ion','Ca')
        self.Xpower = 1 # This will create HHGate instance xGate inside the Ca channel
        self.Ypower = 1 # This will create HHGate instance yGate inside the Ca channel
        ## Below gates get created after Xpower or Ypower are set to nonzero values
        ## I don't anymore have to explicitly create these attributes in the class
        #self.xGate = moose.HHGate(self.path + "/xGate")
        #self.yGate = moose.HHGate(self.path + "/yGate")
        self.xGate.A.xmin = VMIN
        self.xGate.A.xmax = VMAX
        self.xGate.A.xdivs = NDIVS
        self.xGate.B.xmin = VMIN
        self.xGate.B.xmax = VMAX
        self.xGate.B.xdivs = NDIVS
        self.yGate.A.xmin = VMIN
        self.yGate.A.xmax = VMAX
        self.yGate.A.xdivs = NDIVS
        self.yGate.B.xmin = VMIN
        self.yGate.B.xmax = VMAX
        self.yGate.B.xdivs = NDIVS
        
        v = VMIN

        for i in range(NDIVS+1):
            self.xGate.A[i] = calc_Ca_alpha_s(v)
            self.xGate.B[i] = calc_Ca_alpha_s(v) + calc_Ca_beta_s(v)
            self.yGate.A[i] = calc_Ca_alpha_r(v)
            self.yGate.B[i] = calc_Ca_alpha_r(v) + calc_Ca_beta_r(v)
            v = v + dv