Stochastic Dynamics of Electrical Membrane with Voltage-Dependent Ion Channel Fluctuations

Abstract

Brownian ratchet like stochastic theory for the electrochemical membrane system of Hodgkin-Huxley (HH) is developed. The system is characterized by a continuous variable Qm(t), representing mobile membrane charge density, and a discrete variable Kt representing ion channel conformational dynamics. A Nernst-Planck-Nyquist-Johnson type equilibrium is obtained when multiple conducting ions have a common reversal potential. Detailed balance yields a previously unknown relation between the channel switching rates and membrane capacitance, bypassing Eyring-type explicit treatment of gating charge kinetics. From a molecular structural standpoint, membrane charge Qm is a more natural dynamic variable than potential Vm; our formalism treats Qm-dependent conformational transition rates λij as intrinsic parameters. Therefore in principle, λij vs. Vm is experimental protocol dependent,e.g., different from voltage or charge clamping measurements. For constant membrane capacitance per unit area Cm and neglecting membrane potential induced by gating charges, Vm=Qm/Cm, and HH's formalism is recovered. The presence of two types of ions, with different channels and reversal potentials, gives rise to a nonequilibrium steady state with positive entropy production ep. For rapidly fluctuating channels, an expression for ep is obtained.