TITLE Low voltage activated calcium current (CaLVA) of deep cerebellar nucleus (DCN) neuron
COMMENT
This mechanism and the other calcium channel (CaHVA.mod) are the only channel
mechanisms of the DCN model that use the GHK mechanism to calculate reversal
potential. Thus, extracellular Ca concentration is of importance and shall be
set from hoc to 2mM, using: "calo0_ca_ion = 2".
The calcium that this channel lets through feeds into the CalConc.mod mechanism
while calcium entry via the CaHVA channel is tracked by CalConc.mod.
ENDCOMMENT
NEURON {
SUFFIX CaLVA
USEION cal READ cali, calo WRITE ical VALENCE 2
RANGE perm, ical, m, h, cali
GLOBAL qdeltat
}
UNITS {
(mA) = (milliamp)
(mV) = (millivolt)
(molar) = (1/liter)
(mM) = (millimolar)
}
PARAMETER {
qdeltat = 1
perm = 1 (cm/seconds)
}
ASSIGNED {
v (mV)
cali (mM)
calo (mM)
ical (mA/cm2)
minf
hinf
taum (ms)
tauh (ms)
celsius (degC)
T (kelvin)
A (1)
}
STATE {
m
h
}
INITIAL {
T = 273.15 + celsius
rate(v)
m = minf
h = hinf
}
BREAKPOINT {
SOLVE states METHOD cnexp
A = getGHKexp(v)
: "4.47814e6 * v / T" in the following is the simplification of the GHK
: current equation's (z^2 * F^2 * (0.001) * v) / (R * T). [*(0.001) is to get
: volt from NEURON's mV.] Together with the simplification in getGHKexp()
: (below), this speeds up the whole DCN simulation (without synapses) by 8%.
: The division of the calcium concentrations (mM) by 1000 gives molar as
: required by the GHK current equation.
ical = perm * m*m * h * (4.47814e6 * v / T) * ((cali/1000) - (calo/1000) * A) / (1 - A)
}
DERIVATIVE states {
rate(v)
m' = (minf - m)/taum
h' = (hinf - h)/tauh
}
PROCEDURE rate(v(mV)) {
TABLE minf, taum, hinf, tauh FROM -150 TO 100 WITH 300
minf = 1 / (1 + exp((v + 56) / -6.2))
taum = 0.333 / (exp((v + 131) / -16.7) + exp((v + 15.8) / 18.2)) + 0.204
taum = taum / qdeltat
hinf = 1 / (1 + exp((v + 80) / 4))
if (v < -81) {
tauh = 0.333 * exp((v + 466) / 66)
} else {
tauh = 0.333 * exp((v + 21) / -10.5) + 9.32
}
tauh = tauh / qdeltat
}
FUNCTION getGHKexp(v(mV)) {
TABLE DEPEND T FROM -150 TO 100 WITH 300
getGHKexp = exp(-23.20764929 * v / T): =the calculated values of
: getGHKexp = exp((-z * F * (0.001) * v) / (R * T)).
}