Hybrid Integrate-and-Fire Model of a Bursting Neuron

Barbara J. Breen; William C. Gerken; Robert J. Butera

doi:10.1162/089976603322518768

Hybrid Integrate-and-Fire Model of a Bursting Neuron

Barbara J. Breen, William C. Gerken, Robert J. Butera

Finance and Quantitative Methods

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15 Scopus citations

Abstract

We present a reduction of a Hodgkin-Huxley (HH)-style bursting model to a hybridized integrate-and-fire (IF) formalism based on a thorough bi-furcation analysis of the neuron's dynamics. The model incorporates HH-style equations to evolve the subthreshold currents and includes IF mechanisms to characterize spike events and mediate interactions between the subthreshold and spiking currents. The hybrid IF model successfully reproduces the dynamic behavior and temporal characteristics of the full model over a wide range of activity, including bursting and tonic firing. Comparisons of timed computer simulations of the reduced model and the original model for both single neurons and moderately sized networks (n ≤ 500) show that this model offers improvement in computational speed over the HH-style bursting model.

Original language	English
Pages (from-to)	2843-2862
Number of pages	20
Journal	Neural Computation
Volume	15
Issue number	12
DOIs	https://doi.org/10.1162/089976603322518768
State	Published - Dec 2003

ASJC Scopus subject areas

Arts and Humanities (miscellaneous)
Cognitive Neuroscience

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abstract = "We present a reduction of a Hodgkin-Huxley (HH)-style bursting model to a hybridized integrate-and-fire (IF) formalism based on a thorough bi-furcation analysis of the neuron's dynamics. The model incorporates HH-style equations to evolve the subthreshold currents and includes IF mechanisms to characterize spike events and mediate interactions between the subthreshold and spiking currents. The hybrid IF model successfully reproduces the dynamic behavior and temporal characteristics of the full model over a wide range of activity, including bursting and tonic firing. Comparisons of timed computer simulations of the reduced model and the original model for both single neurons and moderately sized networks (n ≤ 500) show that this model offers improvement in computational speed over the HH-style bursting model.",

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AB - We present a reduction of a Hodgkin-Huxley (HH)-style bursting model to a hybridized integrate-and-fire (IF) formalism based on a thorough bi-furcation analysis of the neuron's dynamics. The model incorporates HH-style equations to evolve the subthreshold currents and includes IF mechanisms to characterize spike events and mediate interactions between the subthreshold and spiking currents. The hybrid IF model successfully reproduces the dynamic behavior and temporal characteristics of the full model over a wide range of activity, including bursting and tonic firing. Comparisons of timed computer simulations of the reduced model and the original model for both single neurons and moderately sized networks (n ≤ 500) show that this model offers improvement in computational speed over the HH-style bursting model.

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Hybrid Integrate-and-Fire Model of a Bursting Neuron

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