CA1 network model for place cell dynamics (Turi et al 2019)

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Accession:246546
Biophysical model of CA1 hippocampal region. The model simulates place cells/fields and explores the place cell dynamics as function of VIP+ interneurons.
Reference:
1 . Turi GF, Li W, Chavlis S, Pandi I, O’Hare J, Priestley JB, Grosmark AD, Liao Z, Ladow M, Zhang JF, Zemelman BV, Poirazi P, Losonczy A (2019) Vasoactive Intestinal Polypeptide-Expressing Interneurons in the Hippocampus Support Goal-Oriented Spatial Learning Neuron
Citations  Citation Browser
Model Information (Click on a link to find other models with that property)
Model Type: Realistic Network;
Brain Region(s)/Organism: Hippocampus; Mouse;
Cell Type(s): Hippocampus CA1 pyramidal GLU cell; Hippocampus CA1 basket cell; Hippocampus CA1 basket cell - CCK/VIP; Hippocampus CA1 bistratified cell; Hippocampus CA1 axo-axonic cell; Hippocampus CA1 stratum oriens lacunosum-moleculare interneuron ; Hippocampal CA1 CR/VIP cell;
Channel(s): I A; I h; I K,Ca; I Calcium; I Na, leak; I K,leak; I M;
Gap Junctions:
Receptor(s): GabaA; GabaB; NMDA; AMPA;
Gene(s):
Transmitter(s):
Simulation Environment: NEURON; Brian;
Model Concept(s): Place cell/field;
Implementer(s): Chavlis, Spyridon [schavlis at imbb.forth.gr]; Pandi, Ioanna ;
Search NeuronDB for information about:  Hippocampus CA1 pyramidal GLU cell; GabaA; GabaB; AMPA; NMDA; I A; I K,leak; I M; I h; I K,Ca; I Calcium; I Na, leak;
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Turi_et_al_2018
mechanisms
ANsyn.mod
bgka.mod
burststim2.mod *
cad.mod
cadyn.mod
cadyn_new.mod
cagk.mod *
cal.mod
calH.mod *
cancr.mod
car.mod *
cat.mod
ccanl.mod *
gskch.mod
h.mod
hha_old.mod *
hha2.mod
hNa.mod *
IA.mod
iccr.mod
ichan2.mod
ichan2aa.mod
ichan2bc.mod
ichan2bs.mod
ichan2vip.mod
Ih.mod *
Ihvip.mod
ikscr.mod *
kad.mod *
kadistcr.mod
kap.mod
Kaxon.mod
kca.mod
Kdend.mod
kdrcr.mod *
km.mod
Ksoma.mod
LcaMig.mod *
my_exp2syn.mod
Naaxon.mod
Nadend.mod
nafcr.mod *
nap.mod
Nasoma.mod
nca.mod *
nmda.mod
regn_stim.mod
somacar.mod
STDPE2Syn.mod *
vecstim.mod *
                            
TITLE N-type calcium channel 
: used in somatic and dendritic regions 
: After Borg 
: Updated by Maria Markaki  03/12/03

NEURON {
	SUFFIX cancr
	USEION ca READ cai, eca WRITE ica 
    RANGE gcabar, ica, po
	GLOBAL hinf, minf, s_inf
}

UNITS {
	(mA)    = (milliamp)
	(mV)    = (millivolt)
	(molar) = (1/liter)
	(mM)    =	(millimolar)
	FARADAY = (faraday) (coulomb)
	R       = (k-mole) (joule/degC)
}

PARAMETER {           :parameters that can be entered when function is called in cell-setup 
	gcabar = 0      (mho/cm2)  : initialized conductance
  	ki     = 0.025  (mM)            :test middle point of inactivation fct
	zetam  = -3.4
	zetah  = 2
	vhalfm = -21    (mV)
	vhalfh = -40    (mV)
	tm0    = 1.5    (ms)
	th0    = 75     (ms)
	taumin = 2      (ms)            : minimal value of the time cst
}



ASSIGNED {     : parameters needed to solve DE
	v            (mV)
	celsius      (degC)
	ica          (mA/cm2)
	po
	cai          (mM)       :5e-5 initial internal Ca++ concentration
	eca          (mV)
    minf
    hinf
	s_inf
}


FUNCTION h2(cai(mM)) {
	h2 = ki/(ki+cai)
}



STATE {	
	m 
	h 
	s
}  

INITIAL {
	rates(v,cai)
    m = minf
    h = hinf
	s = s_inf
}

BREAKPOINT {
	SOLVE states METHOD cnexp
	po = m*m*h
 	ica = gcabar *po*h2(cai) * (v - eca)

}


FUNCTION ghk(v(mV), ci(mM), co(mM)) (.001 coul/cm3) {
	LOCAL z, eci, eco
	z = (1e-3)*2*FARADAY*v/(R*(celsius+273.15))
	eco = co*efun(z)
	eci = ci*efun(-z)
	:high cao charge moves inward
	:negative potential charge moves inward
	ghk = (.001)*2*FARADAY*(eci - eco)
}

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

DERIVATIVE states {
	rates(v,cai)
	m' = (minf -m)/tm0
	h'=  (hinf - h)/th0
	s' = (s_inf-s)/taumin
}



PROCEDURE rates(v (mV), cai(mM)) { 
    
    LOCAL a, b, alpha2
        
	a = alpm(v)
	minf = 1/(1+a)
        
    b = alph(v)
	hinf = 1/(1+b)
	
	alpha2 = (ki/cai)^2
	s_inf = alpha2 / (alpha2 + 1)
}




FUNCTION alpm(v(mV)) {
UNITSOFF
  alpm = exp(1.e-3*zetam*(v-vhalfm)*9.648e4/(8.315*(273.16+celsius))) 
UNITSON
}

FUNCTION alph(v(mV)) {
UNITSOFF
  alph = exp(1.e-3*zetah*(v-vhalfh)*9.648e4/(8.315*(273.16+celsius))) 
UNITSON
}