The action potential in mammalian central neurons
Top Cited Papers
- 1 June 2007
- journal article
- review article
- Published by Springer Nature in Nature Reviews Neuroscience
- Vol. 8 (6), 451-465
- https://doi.org/10.1038/nrn2148
Abstract
The action potential of the squid giant axon is formed by just two voltage-dependent conductances in the cell membrane, yet mammalian central neurons typically express more than a dozen different types of voltage-dependent ion channels. This rich repertoire of channels allows neurons to encode information by generating action potentials with a wide range of shapes, frequencies and patterns. Recent work offers an increasingly detailed understanding of how the expression of particular channel types underlies the remarkably diverse firing behaviour of various types of neurons.Keywords
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