: Photoreceptor Kx h Ca channel
NEURON
{
SUFFIX CPR
USEION Ca WRITE iCa VALENCE 2
USEION Cl WRITE iCl VALENCE 1
USEION Kca WRITE iKca VALENCE 1
NONSPECIFIC_CURRENT iCGMP
RANGE gCabar, gCa, eCa, SCa, VhalfCa, aoCa
RANGE gClbar,gCl, eCl, SCl
RANGE gKcabar,gKca, eKca
RANGE gCGMP, eCGMP
:temporal parameters
RANGE FactorCaI
RANGE mCl, Cas
}
UNITS
{
(mA) = (milliamp)
(mV) = (millivolt)
(mS) = (millimho)
(mol)= (1)
(M) = (mol/liter)
(uM) = (micro M)
}
PARAMETER
{
: Calcium channel
gCabar = 4.9 (mS/cm2) <0,1e9>
eCa = 40 (mV)
aoCa = 0.0031 (/ms)
VhalfCa=-16.6 (mV)
SCa =5.7 (mV)
: Cl channel
eCl= -45 (mV)
gClbar = 6.5 (mS/cm2) <0,1e9>
SCl = 0.09 (uM)
Clh = 0.37 (uM)
FactorCaI = 0.5
:Ca-dependent K current
eKca=-80 (mV)
gKcabar = 0.5 (mS/cm2)
: cGMP gated channel
gCGMP= 0 (mS/cm2)
:1.8 (mS/cm2)
eCGMP=0.8 (mV)
}
STATE
{
nCa
mKca
}
ASSIGNED
{
v (mV)
iCa (mA/cm2)
iCl (mA/cm2)
iCGMP (mA/cm2)
iKca (mA/cm2)
:Ca-dependent potassium channel, Kca
infmKca
taumKca (ms)
infCa
tauCa (ms)
Cas (uM)
mCl
: the paremeter for activation
mKca1
gKca (mho/cm2)
gCa (mho/cm2)
gCl (mho/cm2)
}
INITIAL
{
rate(v)
nCa = infCa
mKca= infmKca
}
BREAKPOINT
{
SOLVE states METHOD cnexp
gCa = (0.001)*gCabar*nCa
iCa = gCa*(v - eCa)
UNITSOFF
:if (iCa >= 0)
:{
: Cas =0
:}
:if (iCa < 0)
:{
Cas =-0.2+FactorCaI * (-iCa) * 1 * 0.5 /(1.6e-19)/ (6.023e23) * 1e-6 *1e14
: mA/cm2 * ms-> n coul/cm2 ->n e /cm2-> nmol/cm2 -> mol /cm2 scale factor
: all the calculation without consideration of volume
: }
mCl = 1/(1+ exp ( (Clh - Cas)/ SCl ) )
gCl = (0.001)* gClbar * mCl
iCl = gCl*(v-eCl)
mKca1=Cas/(Cas+0.3)
gKca=(0.001)*gKcabar*mKca*mKca*mKca1
iKca=gKca*(v-eKca)
UNITSON
iCGMP = (0.001)*gCGMP*(v-eCGMP)
: the current is in the unit of mA/cm2
}
DERIVATIVE states
{
rate(v)
nCa' = (infCa - nCa)/tauCa
mKca'= (infmKca - mKca ) /taumKca
}
UNITSOFF
FUNCTION alphamKca(v(mV)) (/ms)
{
alphamKca = (0.001)*15*(80-v)/ ( exp( (80-v)/40 ) -1)
:alter from orginal settings where it is in the unit of 1/s
}
FUNCTION betamKca (v(mV)) (/ms)
{
betamKca = (0.001)*20*exp (-v/35)
}
UNITSON
FUNCTION alphaCa(v(mV))(/ms)
{
alphaCa = aoCa*exp( (v - VhalfCa)/(2*SCa) )
}
FUNCTION betaCa(v(mV))(/ms)
{
betaCa = aoCa*exp( - ( v-VhalfCa)/(2*SCa) )
}
PROCEDURE rate(v (mV))
{
LOCAL a, b
a = alphamKca(v)
b = betamKca(v)
taumKca = 1/(a + b)
infmKca = a/(a + b)
a = alphaCa(v)
b = betaCa(v)
tauCa = 1/(a + b)
infCa = a/(a + b)
}