Derivation of Hodgkin-Huxley equations for a Na+ channel from a master equation for coupled activation and inactivation

TL;DR

This paper derives Hodgkin-Huxley equations for Na+ channels from a master equation framework, linking activation and inactivation processes to channel conductance with voltage-dependent rates.

Contribution

It introduces a derivation of Hodgkin-Huxley equations from a master equation considering coupled activation and inactivation sensors in Na+ channels, providing a more comprehensive model.

Findings

Derived a generalized Hodgkin-Huxley model incorporating activation and inactivation coupling.

Showed voltage dependence of inactivation and recovery rates matches empirical data.

Demonstrated saturation behavior of rate functions at extreme voltages.

Abstract

The Na+ current in nerve and muscle membranes may be described in terms of the activation variable m(t) and the inactivation variable h(t), which are dependent on the transitions of S4 sensors of each of the Na+ channel domains DI to DIV. The time-dependence of the Na+ current and the rate equations satisfied by m(t) and h(t) may be derived from the solution to a master equation which describes the coupling between two or three activation sensors regulating the Na+ channel conductance and a two stage inactivation process. If the inactivation rate from the closed or open states increases as the S4 sensors activate, a more general form for the Hodgkin-Huxley expression for the open state probability may be derived where m(t) is dependent on both activation and inactivation processes. The voltage dependence of the rate functions for inactivation and recovery from inactivation are consistent with the empirically determined expressions, and exhibit saturation for both depolarized and hyperpolarized clamp potentials.