TITLE hh_mod.mod squid sodium, potassium, and leak channels
: Modified from NEURON's built-in hh.mod
: 2021, Janos Brunner
:
: relates to the publication:
: "Small size of recorded neuronal structures confines the accuracy in direct axonal voltage measurements"
: by Viktor Janos Olah, Gergely Tarcsay and Janos Brunner
: ENEURO.0059-21.2021
: scale_na_act, scale_na_inact, scale_k, v_shift_na, v_shift_k are introduced
COMMENT
This is the original Hodgkin-Huxley treatment for the set of sodium,
potassium, and leakage channels found in the squid giant axon membrane.
("A quantitative description of membrane current and its application
conduction and excitation in nerve" J.Physiol. (Lond.) 117:500-544 (1952).)
Membrane voltage is in absolute mV and has been reversed in polarity
from the original HH convention and shifted to reflect a resting potential
of -65 mV.
Remember to set celsius=6.3 (or whatever) in your HOC file.
See squid.hoc for an example of a simulation using this model.
SW Jaslove 6 March, 1992
ENDCOMMENT
UNITS {
(mA) = (milliamp)
(mV) = (millivolt)
(S) = (siemens)
}
? interface
NEURON {
SUFFIX hh_mod
USEION na READ ena WRITE ina
USEION k READ ek WRITE ik
NONSPECIFIC_CURRENT il
RANGE gnabar, gkbar, gl, el, gna, gk, scale_na_act,scale_na_inact,scale_k, v_shift_na,v_shift_k
RANGE minf, hinf, ninf, mtau, htau, ntau
THREADSAFE : assigned GLOBALs will be per thread
}
PARAMETER {
gnabar = .12 (S/cm2) <0,1e9>
gkbar = .036 (S/cm2) <0,1e9>
gl = .0003 (S/cm2) <0,1e9>
el = -80 (mV)
scale_na_act=1 <0.001,1e3>
scale_na_inact=1 <0.001,1e3>
scale_k=1 <0.001,1e3>
v_shift_na=0
v_shift_k=0
}
STATE {
m h n
}
ASSIGNED {
v (mV)
ena (mV)
ek (mV)
gna (S/cm2)
gk (S/cm2)
ina (mA/cm2)
ik (mA/cm2)
il (mA/cm2)
minf hinf ninf
mtau (ms) htau (ms) ntau (ms)
}
? currents
BREAKPOINT {
SOLVE states METHOD cnexp
gna = gnabar*m*m*m*h
ina = gna*(v - ena)
gk = gkbar*n*n*n*n
ik = gk*(v - ek)
il = gl*(v - el)
}
INITIAL {
rates(v)
m = minf
h = hinf
n = ninf
}
? states
DERIVATIVE states {
rates(v)
m' = (minf-m)/mtau
h' = (hinf-h)/htau
n' = (ninf-n)/ntau
}
? rates
PROCEDURE rates(v(mV)) { :Computes rate and other constants at current v.
:Call once from HOC to initialize inf at resting v.
LOCAL alpha, beta, sum
UNITSOFF
alpha = .1 * vtrap(-((v-v_shift_na)+40),10)
beta = 4 * exp(-((v-v_shift_na)+65)/18)
sum = alpha + beta
mtau = 1/(scale_na_act*sum)
minf = alpha/sum
:"h" sodium inactivation system
alpha = .07 * exp(-((v-v_shift_na)+65)/20)
beta = 1 / (exp(-((v-v_shift_na)+35)/10) + 1)
sum = alpha + beta
htau = 1/(scale_na_inact*sum)
hinf = alpha/sum
:"n" potassium activation system
alpha = .01*vtrap(-((v-v_shift_k)+55),10)
beta = .125*exp(-((v-v_shift_k)+65)/80)
sum = alpha + beta
ntau = 1/(scale_k*sum)
ninf = alpha/sum
}
FUNCTION vtrap(x,y) { :Traps for 0 in denominator of rate eqns.
if (fabs(x/y) < 1e-6) {
vtrap = y*(1 - x/y/2)
}else{
vtrap = x/(exp(x/y) - 1)
}
}
UNITSON