Conductance-Based Integrate and Fire Models
Abstract
A conductance-based model of Na+ and K+ currents underlying action potential generation is introduced by simplifying the quantitative model of Hodgkin and Huxley (HH). If the time course of rate constants can be approximated by a pulse, HH equations can be solved analytically. Pulse-based (PB) models generate action potentials very similar to the HH model but are computationally faster. Unlike the classical integrate-and fire (IAF) approach, they take into account the changes of conductances during and after the spike, which have a determinant influence in shaping neuronal responses. Similarities and differences among PB, IAF, and HH models are illustrated for three cases: high-frequency repetitive firing, spike timing following random synaptic inputs, and network behavior in the presence of intrinsic currents.
Cite
Text
Destexhe. "Conductance-Based Integrate and Fire Models." Neural Computation, 1997. doi:10.1162/NECO.1997.9.3.503Markdown
[Destexhe. "Conductance-Based Integrate and Fire Models." Neural Computation, 1997.](https://mlanthology.org/neco/1997/destexhe1997neco-conductancebased/) doi:10.1162/NECO.1997.9.3.503BibTeX
@article{destexhe1997neco-conductancebased,
title = {{Conductance-Based Integrate and Fire Models}},
author = {Destexhe, Alain},
journal = {Neural Computation},
year = {1997},
pages = {503-514},
doi = {10.1162/NECO.1997.9.3.503},
volume = {9},
url = {https://mlanthology.org/neco/1997/destexhe1997neco-conductancebased/}
}