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 = * 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 : : This file was modified by Yiota Poirazi (poirazi@LNC.usc.edu) on April 18, 2001 to account for the sharp : Ca++ spike repolarization observed in: Golding, N. Jung H-Y., Mickus T. and Spruston N : "Dendritic Calcium Spike Initiation and Repolarization are controlled by distinct potassium channel : subtypes in CA1 pyramidal neurons". J. of Neuroscience 19(20) 8789-8798, 1999. : : factor 10000 is replaced by 10000/18 needed in ca entry : taur --rate of calcium removal-- is replaced by taur*7 (7 times faster) INDEPENDENT {t FROM 0 TO 1 WITH 1 (ms)} NEURON { SUFFIX cad USEION ca READ ica, cai WRITE cai RANGE ca GLOBAL depth,cainf,taur } UNITS { (molar) = (1/liter) : moles do not appear in units (mM) = (millimolar) (um) = (micron) (mA) = (milliamp) (msM) = (ms mM) FARADAY = (faraday) (coulomb) } PARAMETER { depth = .1 (um) : depth of shell taur = 200 (ms) : rate of calcium removal cainf = 100e-6(mM) cai (mM) } STATE { ca (mM) } INITIAL { ca = cainf } ASSIGNED { ica (mA/cm2) drive_channel (mM/ms) } BREAKPOINT { SOLVE state METHOD euler } DERIVATIVE state { drive_channel = - (10000) * ica / (2 * FARADAY * depth) if (drive_channel <= 0.) { drive_channel = 0. } : cannot pump inward :ca' = drive_channel + (cainf-ca)/taur ca' = drive_channel/18 + (cainf -ca)/taur*7 cai = ca }