: $Id: ntt.mod,v 1.7 2003/12/11 00:37:51 billl Exp $
TITLE Low threshold calcium current
:
: Ca++ current responsible for low threshold spikes (LTS)
: RETICULAR THALAMUS
: Differential equations
:
: Model of Huguenard & McCormick, J Neurophysiol 68: 1373-1383, 1992.
: The kinetics is described by standard equations (NOT GHK)
: using a m2h format, according to the voltage-clamp data
: (whole cell patch clamp) of Huguenard & Prince, J Neurosci.
: 12: 3804-3817, 1992.
:
: - Kinetics adapted to fit the T-channel of reticular neuron
: - Q10 changed to 5 and 3
: - Time constant tau_h fitted from experimental data
: - shift parameter for screening charge
:
: ACTIVATION FUNCTIONS FROM EXPERIMENTS (NO CORRECTION)
:
: Reversal potential taken from Nernst Equation
:
: Written by Alain Destexhe, Salk Institute, Sept 18, 1992
:
INDEPENDENT {t FROM 0 TO 1 WITH 1 (ms)}
NEURON {
SUFFIX it2
USEION Ca READ Cai, Cao WRITE iCa VALENCE 2
RANGE gcabar, g, shift1
GLOBAL m_inf, tau_m, h_inf, tau_h, shift2, sm, sh, phi_m, phi_h, hx, mx,rat
}
UNITS {
(molar) = (1/liter)
(mV) = (millivolt)
(mA) = (milliamp)
(mM) = (millimolar)
FARADAY = (faraday) (coulomb)
R = (k-mole) (joule/degC)
}
PARAMETER {
v (mV)
celsius = 36 (degC)
: eCa = 120 (mV)
gcabar = .024 (mho/cm2)
shift1 = -1 (mV)
shift2 = -6 (mV)
sm = 7.4
sh = 5.0
hx = 1.5
mx = 3.0
Cai = 5e-5 (mM) : adjusted for eca=120 mV
Cao = 2 (mM)
rat = 1
}
STATE {
m h
}
ASSIGNED {
iCa (mA/cm2)
g (mho/cm2)
carev (mV)
m_inf
tau_m (ms)
h_inf
tau_h (ms)
phi_m
phi_h
}
BREAKPOINT {
SOLVE castate METHOD cnexp
g = gcabar * m*m*h
iCa = g * ghk(v, Cai, Cao)
}
DERIVATIVE castate {
evaluate_fct(v)
m' = (m_inf - m) / tau_m
h' = (h_inf - h) / tau_h
}
UNITSOFF
INITIAL {
VERBATIM
Cai = _ion_Cai;
Cao = _ion_Cao;
ENDVERBATIM
: Activation functions and kinetics were obtained from
: Huguenard & Prince, and were at 23-25 deg.
: Transformation to 36 deg assuming Q10 of 5 and 3 for m and h
: (as in Coulter et al., J Physiol 414: 587, 1989)
:
phi_m = mx ^ ((celsius-24)/10)
phi_h = hx ^ ((celsius-24)/10)
evaluate_fct(v)
m = m_inf
h = h_inf
}
PROCEDURE evaluate_fct(v(mV)) {
:
: Time constants were obtained from J. Huguenard
:
m_inf = 1.0 / ( 1 + exp(-(v+shift1+50)/sm) )
h_inf = 1.0 / ( 1 + exp((v+shift2+78)/sh) )
tau_m = (2+1.0/(exp((v+shift1+35)/10)+exp(-(v+shift1+100)/15)))/ phi_m
tau_h = (24.22+1.0/(exp((v+55.56)/3.24)+exp(-(v+383.56)/51.26)))/phi_h
}
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)*rat
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)
}
}
UNITSON