Boundary integral formulation for the electrical response of a nerve to an extracellular stimulation

Henriquez Barraza, Fernando Jose

Pontificia Universidad Católica de Chile

Ir al sitio UC

ADMISION

Covid-19

Medios

Biblioteca

Donaciones

Mi Portal UC

Correo
- Correo UC
- Correo GMAIL UC

Información

Tipo de documentocomunicación de congreso

Documentos de este título

Boundary integral formulation for the electrical response of a nerve to an extracellular stimulation.pdf

Datos investigador

Henriquez Barraza, Fernando Jose Jerez Hanckes, Carlos F. Altermatt Couratier, Fernando René

Altmetric

Comparte este registro

We present a two-dimensional boundary integral formulation of nerve impulse propagation. A nerve impulse is a potential difference across the cellular membrane that propagates along the nerve fiber. The traveling transmembrane potential is produced by the transfer of ionic species between the intra- and extra-cellular mediums. This current flux across the membrane-composed of conduction, diffusion and capacitive terms- is regulated by passive and active mechanisms that are highly complicated to describe mathematically from a microscopic point of view. Based on the Hodgkin and Huxley axon model, we propose a well-posed integral formulation based on a quasi-static approximation amenable to time-stepping schemes and discuss first results.

Registro Sencillo
Registro Completo

Autor	Henriquez Barraza, Fernando Jose Jerez Hanckes, Carlos F. Altermatt Couratier, Fernando René
Título	Boundary integral formulation for the electrical response of a nerve to an extracellular stimulation
ISSN	1094-687X
ISSN electrónico	1558-4615
ISBN electrónico	978-1-4577-0216-7
Página inicio	6207
Página final	6010
Fecha de publicación	2013
Resumen	We present a two-dimensional boundary integral formulation of nerve impulse propagation. A nerve impulse is a potential difference across the cellular membrane that propagates along the nerve fiber. The traveling transmembrane potential is produced by the transfer of ionic species between the intra- and extra-cellular mediums. This current flux across the membrane-composed of conduction, diffusion and capacitive terms- is regulated by passive and active mechanisms that are highly complicated to describe mathematically from a microscopic point of view. Based on the Hodgkin and Huxley axon model, we propose a well-posed integral formulation based on a quasi-static approximation amenable to time-stepping schemes and discuss first results.
Derechos	acceso restringido
DOI	10.1109/EMBC.2013.6610971
Editorial	IEEE
Enlace	https://ieeexplore.ieee.org/stamp/stamp.jsp?arnumber=6610971 https://doi.org/10.1109/EMBC.2013.6610971 https://repositorio.uc.cl/handle/11534/63796
Palabra clave	Mathematical model Nerve fibers Electric potential Equations Extracellular Integral equations Biomembranes
Publicado en / Colección	Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC) (35° : 2013 : Osaka, Japón)
Tipo de documento	comunicación de congreso