A New Approach to Define Dynamics of the Ion Channel Gates

A New Approach to Define Dynamics of the Ion Channel Gates

Peer-reviewed article not indexed in WoS or Scopus

Voltage-gated ion channels are of great importance in the generation and propagation of electrical signals in the excitable cellmembranes. How these channels respond to changes in the potential across themembrane has been a challenging problem, and different approaches have been proposed to address the mechanism of voltage sensing and gating in these channels. In this study, we attempt a new approach by considering a simple two-state gate system and applying the path probability method to construct a nonequilibrium statistical mechanical model of the system. The model which is based on the principles of statistical physics provides a firm physical basis for ion channel gating.

Voltage-gated ion channels are of great importance in the generation and propagation of electrical signals in the excitable cellmembranes. How these channels respond to changes in the potential across themembrane has been a challenging problem, and different approaches have been proposed to address the mechanism of voltage sensing and gating in these channels. In this study, we attempt a new approach by considering a simple two-state gate system and applying the path probability method to construct a nonequilibrium statistical mechanical model of the system. The model which is based on the principles of statistical physics provides a firm physical basis for ion channel gating.

(In)Activation gate; Ion channel; Path probability method; Statistical mechanics

(In)Activation gate; Ion channel; Path probability method; Statistical mechanics

OZER, M., ERDEM, R., PROVAZNÍK, I.

2011

01.02.2004

Lippincott Williams & Wilkins

0959-4965

NEUROREPORT

15

2

United States of America

335

4