: $Id: cp.mod,v 1.10 1998/08/16 20:43:43 billl Exp $
TITLE decay of internal calcium concentration
:
: Internal calcium concentration due to calcium currents and pump.
: Differential equations.
:
: Simple model of ATPase pump with 3 kinetic constants (Destexhe 92)
: Cai + P <-> CaP -> Cao + P (k1,k2,k3)
: A Michaelis-Menten approximation is assumed, which reduces the complexity
: of the system to 2 parameters:
: kt = <tot enzyme concentration> * k3 -> TIME CONSTANT OF THE PUMP
: kd = k2/k1 (dissociation constant) -> EQUILIBRIUM CALCIUM VALUE
: The values of these parameters are chosen assuming a high affinity of
: the pump to calcium and a low transport capacity (cfr. Blaustein,
: TINS, 11: 438, 1988, and references therein).
:
: Units checked using "modlunit" -> factor 10000 needed in ca entry
:
: VERSION OF PUMP + DECAY (decay can be viewed as simplified buffering)
:
: All variables are range variables
:
:
: This mechanism was published in: Destexhe, A. Babloyantz, A. and
: Sejnowski, TJ. Ionic mechanisms for intrinsic slow oscillations in
: thalamic relay neurons. Biophys. J. 65: 1538-1552, 1993)
:
: Written by Alain Destexhe, Salk Institute, Nov 12, 1992
:
INDEPENDENT {t FROM 0 TO 1 WITH 1 (ms)}
NEURON {
SUFFIX cad
USEION ca READ ica, cai WRITE cai
RANGE depth,kt,kt2,kd,cainf,taur,k,taur2,cainf2
RANGE drive_channel,drive_pump,drive_pump2
}
UNITS {
(molar) = (1/liter) : moles do not appear in units
(mM) = (millimolar)
(um) = (micron)
(mA) = (milliamp)
(msM) = (ms mM)
}
CONSTANT {
FARADAY = 96489 (coul) : moles do not appear in units
: FARADAY = 96.489 (k-coul) : moles do not appear in units
}
PARAMETER {
depth = .1 (um) : depth of shell
taur = 700 (ms) : rate of calcium removal
taur2 = 70 (ms) : rate of calcium removal
cainf = 1e-8 (mM)
cainf2 = 5e-5 (mM)
cainit = 5e-5
kt = 1 (mM/ms) : estimated from k3=.5, tot=.001
kt2 = 1 (mM/ms) : estimated from k3=.5, tot=.001
kd = 5e-4 (mM) : estimated from k2=250, k1=5e5
kd2 = 1e-7 (mM) : estimated from k2=250, k1=5e5
k = 1
}
STATE {
cai (mM) <1e-8> : to have tolerance of .01nM
}
INITIAL {
cai = cainit
}
ASSIGNED {
ica (mA/cm2)
drive_channel (mM/ms)
drive_pump (mM/ms)
drive_pump2 (mM/ms)
}
BREAKPOINT {
SOLVE state METHOD cnexp
}
DERIVATIVE state {
drive_channel = - (k*10000) * ica / (2 * FARADAY * depth)
if (drive_channel<=0.) { drive_channel = 0. }: cannot pump inward
: drive_pump = -tot * k3 * cai / (cai + ((k2+k3)/k1) ) : quasistat
drive_pump = -kt * cai / (cai + kd ) : Michaelis-Menten
drive_pump2 = -kt2 * cai / (cai + kd2 ) : Michaelis-Menten
cai' = drive_channel+drive_pump+drive_pump2+(cainf-cai)/taur+(cainf2-cai)/taur2
}