Electrochemical response of biological membranes to localized currents and external electric fields

TL;DR

This paper models the electrochemical response of biological membranes under localized currents and external electric fields, revealing how screening effects and multiscale coupling influence membrane potential dynamics.

Contribution

It introduces a multiscale analytical framework for membrane-electrolyte systems, deriving explicit expressions for transmembrane potential considering electrode effects.

Findings

Diffuse charge layers reach quasi-steady state rapidly

Bulk electrolyte remains electroneutral during response

Equivalent circuit models describe long-term behavior

Abstract

Electrochemical phenomena in biology often unfold in confined geometries where micrometer- to millimeter-scale domains coexist with nanometer-scale interfacial diffuse charge layers. We analyze a model lipid membrane-electrolyte system where an ion channel-like current flows across the membrane while parallel electrodes simultaneously apply a step voltage, emulating an extrinsic electric field. Matched asymptotic expansions of the Poisson-Nernst-Planck equations show that, under physiological conditions, the diffuse charge layers rapidly reach a quasi-steady state, and the bulk electrolyte remains electroneutral. As a result, all free charge is confined to the nanometer-scale screening layers at the membrane and electrode interfaces. The bulk electric potential satisfies Laplace's equation, and is dynamically coupled to the interfacial layers through time-dependent boundary conditions. This multiscale coupling partitions the space-time response into distinct regimes. At sufficiently long times, we show that the system can be represented by an equivalent circuit analogous to those used in classical cable theory. We derive closed-form expressions of the transmembrane potential within each regime, and verify them against nonlinear numerical simulations. Our results show how electrode-induced screening and confinement effects influence the electrochemical response over multiple length and time scales in biological systems.