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Electromagnetic induction between axons and their schwann cell myelin-protein sheaths

G. Goodman

Galil Genetic Analysis, Kazerin 12900, Israel

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and

D. Bercovich

Faculty of Life Sciences, Tel-Hai College, Galilee 12210, Israel

Human Molecular Genetics and Pharmacogenetics, Migal Biotechnology Institute, Galilee, Kiryat Shmona 11016, Israel

Corresponding author.

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https://doi.org/10.1142/S0219635213500295Cited by:4 (Source: Crossref)

Abstract

Two concepts have long dominated vertebrate nerve electrophysiology: (a) Schwann cell-formed myelin sheaths separated by minute non-myelinated nodal gaps and spiraling around axons of peripheral motor nerves reduce current leakage during propagation of trains of axon action potentials; (b) "jumping" by action potentials between successive nodes greatly increases signal conduction velocity. Long-held and more recent assumptions and issues underlying those concepts have been obscured by research emphasis on axon-sheath biochemical symbiosis and nerve regeneration. We hypothesize: mutual electromagnetic induction in the axon-glial sheath association, is fundamental in signal conduction in peripheral and central myelinated axons, explains the g-ratio and is relevant to animal navigation.

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