A Computational Approach for the Inverse Problem of Neuronal Conductances Determination

Overview

Journal J Comput Neurosci

Specialties Biology
Neurology

Date 2020 Jul 7

PMID 32627092

Citations 1

Authors

Jemy A Mandujano Valle

Alexandre L Madureira

Antonio Leitao

Affiliations

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Abstract

The derivation by Alan Hodgkin and Andrew Huxley of their famous neuronal conductance model relied on experimental data gathered using the squid giant axon. However, the experimental determination of conductances of neurons is difficult, in particular under the presence of spatial and temporal heterogeneities, and it is also reasonable to expect variations between species or even between different types of neurons of the same species.We tackle the inverse problem of determining, given voltage data, conductances with non-uniform distribution in the simpler setting of a passive cable equation, both in a single or branched neurons. To do so, we consider the minimal error iteration, a computational technique used to solve inverse problems. We provide several numerical results showing that the method is able to provide reasonable approximations for the conductances, given enough information on the voltages, even for noisy data.

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