A numerical method for cellular electrophysiology based on the electrodiffusion equations with internal boundary conditions at membranes

Yoichiro Mori; Charles S. Peskin

doi:10.2140/camcos.2009.4.85

A numerical method for cellular electrophysiology based on the electrodiffusion equations with internal boundary conditions at membranes

Yoichiro Mori, Charles S. Peskin

Mathematics

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32 Scopus citations

Abstract

We present a numerical method for solving the system of equations of a model of cellular electrical activity that takes into account both geometrical effects and ionic concentration dynamics. A challenge in constructing a numerical scheme for this model is that its equations are stiff: There is a time scale associated with "diffusion" of the membrane potential that is much faster than the time scale associated with the physical diffusion of ions. We use an implicit discretization in time and a finite volume discretization in space. We present convergence studies of the numerical method for cylindrical and two-dimensional geometries for several cases of physiological interest.

Original language	English (US)
Pages (from-to)	85-134
Number of pages	50
Journal	Communications in Applied Mathematics and Computational Science
Volume	4
Issue number	1
DOIs	https://doi.org/10.2140/camcos.2009.4.85
State	Published - 2009

Keywords

Electrodiffusion
Ephaptic transmission
Finite volume method
Three-dimensional cellular electrophysiology

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AB - We present a numerical method for solving the system of equations of a model of cellular electrical activity that takes into account both geometrical effects and ionic concentration dynamics. A challenge in constructing a numerical scheme for this model is that its equations are stiff: There is a time scale associated with "diffusion" of the membrane potential that is much faster than the time scale associated with the physical diffusion of ions. We use an implicit discretization in time and a finite volume discretization in space. We present convergence studies of the numerical method for cylindrical and two-dimensional geometries for several cases of physiological interest.

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A numerical method for cellular electrophysiology based on the electrodiffusion equations with internal boundary conditions at membranes

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