TITLE All ion channels used in GP models : : Na+, K, Ca_T, Leakage and Ca diffusion : : Added AHP current 9/6/2005 Philip Hahn : NEURON { SUFFIX GPeA NONSPECIFIC_CURRENT ilk USEION ca READ cai, cao WRITE ica, cai USEION k READ ki, ko WRITE ik USEION na READ nai, nao WRITE ina RANGE ina, ik, ica RANGE gnabar, ena, m_inf, h_inf, tau_h, tau_m : fast sodium RANGE gkdrbar, ek, n_inf, tau_n, ikD : delayed K rectifier RANGE gl, el, ilk : leak RANGE gcatbar, eca, p_inf, tau_p, q_inf, tau_q, icaT : T-type ca current RANGE gkcabar, ek, r_inf, ikAHP : ca dependent AHP K current RANGE kca, vol, caGain : ca dynamics } UNITS { (mA) = (milliamp) (mV) = (millivolt) (S) = (siemens) (molar) = (1/liter) (mM) = (millimolar) FARADAY = (faraday) (coulomb) :units are really coulombs/mole PI = (pi) (1) } PARAMETER { R = 8.31441 (Gas constant) T (Absolute temp) celsius (degC) :Fast Na channel gnabar = 49e-3 (S/cm2) theta_m = -38 (mV) theta_h = -45.5 (mV) k_m = -7 (mV) k_h = 6.4 (mV) tau_m0 = 0.001 (ms) tau_m1 = 0.1 (ms) tau_h0 = 0 (ms) tau_h1 = 4.5 (ms) tht_m = -53 (mV) tht_h1 = -50 (mV) tht_h2 = -50 (mV) sig_m = -0.7 (mV) sig_h1 = -15 (mV) sig_h2 = 16 (mV) : delayed K rectifier gkdrbar = 57e-3 (S/cm2) theta_n = -42 (mV) k_n = -14 (mV) tau_n0 = 0 (ms) tau_n1 = 2.4 (ms) tht_n1 = -40 (mV) tht_n2 = -40 (mV) sig_n1 = -40 (mV) sig_n2 = 50 (mV) :Leakage current gl = 0.35e-3 (S/cm2) el = -60 (mV) :Ca dynamics kca = 2 (1/ms) area vol = 3.355e-11 (L) :~20um radius sphere caGain = .1 :T-type ca current gcatbar = 5e-3 (S/cm2) theta_p = -56 (mV) theta_q = -85 (mV) k_p = -6.7 (mV) k_q = 5.8 (mV) tau_p0 = 5 (ms) tau_p1 = 0.33 (ms) tau_q0 = 0 (ms) tau_q1 = 400 (ms) tht_p1 = -27 (mV) tht_p2 = -102 (mV) tht_q1 = -50 (mV) tht_q2 = -50 (mV) sig_p1 = -10 (mV) sig_p2 = 15 (mV) sig_q1 = -15 (mV) sig_q2 = 16 (mV) :AHP current (Ca dependent K current) gkcabar = 1e-3 (S/cm2) theta_r = 0.17e-3 (mM) k_r = -0.08e-3 (mM) tau_r = 2 (ms) power_r = 2 } ASSIGNED { v (mV) ina (mA/cm2) ik (mA/cm2) ikD (mA/cm2) ikAHP (mA/cm2) ica (mA/cm2) icaT (mA/cm2) ilk (mA/cm2) :Fast Na h_inf tau_h (ms) m_inf tau_m (ms) ena (mV) := 60 :K rectifier n_inf tau_n (ms) ek (mV) := -90 :T-type ca current p_inf q_inf tau_p (ms) tau_q (ms) eca (mV) :calc from Nernst :AHP (Ca dependent K current) r_inf } STATE { m h n p q cai (mM) <1e-10> cao (mM) <1e-10> nai (mM) <1e-10> nao (mM) <1e-10> ki (mM) <1e-10> ko (mM) <1e-10> r } BREAKPOINT { SOLVE states METHOD cnexp T = 273 + celsius - 9.5 ena = -(R*T)/FARADAY*log(nai/nao)*1000 ek = (R*T)/FARADAY*log(ko/ki)*1000 eca = -(R*T)/FARADAY*log(cai/cao)*1000/2 ina = gnabar * m*m*m*h * (v - ena) ikD = gkdrbar * n^4 * (v - ek) ikAHP = gkcabar * (v - ek)*r^(power_r) ik=ikD+ikAHP ilk = gl * (v - el) ica = gcatbar * p*p*q * (v - eca) } DERIVATIVE states { evaluate_fct(v) h' = (h_inf - h)/tau_h m' = (m_inf - m)/tau_m n' = (n_inf - n)/tau_n p' = (p_inf - p)/tau_p q' = (q_inf - q)/tau_q :(Ica mA/cm2)*(area um2)*(1e-8 cm2/um2)*(1e-3 A/mA)*(1/(2*F) mol/C)*(1e-3 sec/msec)*(1e3 mMol/mol)(1/volume 1/L)=(mM/msec) cai' = caGain*(-ica*area*1e-11/(2*FARADAY*vol) - kca*cai) r' = (r_inf - r)/tau_r } UNITSOFF INITIAL { evaluate_fct(v) m = m_inf h = h_inf n = n_inf p = p_inf q = q_inf r = r_inf } PROCEDURE evaluate_fct(v(mV)) { h_inf = 1/(1+exp((v-theta_h)/k_h)) m_inf = 1/(1+exp((v-theta_m)/k_m)) tau_h = tau_h0 + tau_h1/(exp(-(v-tht_h1)/sig_h1) + exp(-(v-tht_h2)/sig_h2)) tau_m = tau_m0 + tau_m1/(1+exp(-(v-tht_m)/sig_m)) n_inf = 1/(1+exp((v-theta_n)/k_n)) tau_n = tau_n0 + tau_n1/(exp(-(v-tht_n1)/sig_n1) + exp(-(v-tht_n2)/sig_n2)) p_inf = 1/(1+exp((v-theta_p)/k_p)) q_inf = 1/(1+exp((v-theta_q)/k_q)) tau_p = tau_p0 + tau_p1/(exp(-(v-tht_p1)/sig_p1) + exp(-(v-tht_p2)/sig_p2)) tau_q = tau_q0 + tau_q1/(exp(-(v-tht_q1)/sig_q1) + exp(-(v-tht_q2)/sig_q2)) r_inf = 1/(1+exp((cai-theta_r)/k_r)) } UNITSON