Electric field modulation of synchronization in neuronal networks

E. H. Park; P. So; E. Barreto; B. J. Gluckman; S. J. Schiff

doi:10.1016/s0925-2312(02)00820-2

Electric field modulation of synchronization in neuronal networks

E. H. Park, P. So, E. Barreto, B. J. Gluckman, S. J. Schiff

Research output: Contribution to journal › Article › peer-review

21 Scopus citations

Abstract

Motivated by the observation that applied electric fields modulate hippocampal seizures, and that seizures may be asynchronous, we modeled synaptically coupled two-compartment hippocampal pyramidal neurons embedded within an electrically resistive lattice in order to examine network synchronization properties under the influence of externally applied electric fields. Excitatory electric fields were shown to synchronize or desynchronize the network depending on the natural frequency mismatch between the neurons. Such frequency mismatch was found to decrease as a function of increasing electric field amplitude. These findings provide testable hypotheses for future seizure control experiments.

Original language	English (US)
Pages (from-to)	169-175
Number of pages	7
Journal	Neurocomputing
Volume	52-54
DOIs	https://doi.org/10.1016/s0925-2312(02)00820-2
State	Published - Jun 2003

All Science Journal Classification (ASJC) codes

Computer Science Applications
Cognitive Neuroscience
Artificial Intelligence

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10.1016/s0925-2312(02)00820-2

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title = "Electric field modulation of synchronization in neuronal networks",

abstract = "Motivated by the observation that applied electric fields modulate hippocampal seizures, and that seizures may be asynchronous, we modeled synaptically coupled two-compartment hippocampal pyramidal neurons embedded within an electrically resistive lattice in order to examine network synchronization properties under the influence of externally applied electric fields. Excitatory electric fields were shown to synchronize or desynchronize the network depending on the natural frequency mismatch between the neurons. Such frequency mismatch was found to decrease as a function of increasing electric field amplitude. These findings provide testable hypotheses for future seizure control experiments.",

author = "Park, {E. H.} and P. So and E. Barreto and Gluckman, {B. J.} and Schiff, {S. J.}",

note = "Funding Information: This work was supported by NIH K02MH01493, 2R01MH50006, K25 MH01963; NSF IBN 97-27739. ",

year = "2003",

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doi = "10.1016/s0925-2312(02)00820-2",

language = "English (US)",

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T1 - Electric field modulation of synchronization in neuronal networks

AU - Park, E. H.

AU - So, P.

AU - Barreto, E.

AU - Gluckman, B. J.

AU - Schiff, S. J.

N1 - Funding Information: This work was supported by NIH K02MH01493, 2R01MH50006, K25 MH01963; NSF IBN 97-27739.

PY - 2003/6

Y1 - 2003/6

N2 - Motivated by the observation that applied electric fields modulate hippocampal seizures, and that seizures may be asynchronous, we modeled synaptically coupled two-compartment hippocampal pyramidal neurons embedded within an electrically resistive lattice in order to examine network synchronization properties under the influence of externally applied electric fields. Excitatory electric fields were shown to synchronize or desynchronize the network depending on the natural frequency mismatch between the neurons. Such frequency mismatch was found to decrease as a function of increasing electric field amplitude. These findings provide testable hypotheses for future seizure control experiments.

AB - Motivated by the observation that applied electric fields modulate hippocampal seizures, and that seizures may be asynchronous, we modeled synaptically coupled two-compartment hippocampal pyramidal neurons embedded within an electrically resistive lattice in order to examine network synchronization properties under the influence of externally applied electric fields. Excitatory electric fields were shown to synchronize or desynchronize the network depending on the natural frequency mismatch between the neurons. Such frequency mismatch was found to decrease as a function of increasing electric field amplitude. These findings provide testable hypotheses for future seizure control experiments.

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DO - 10.1016/s0925-2312(02)00820-2

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SN - 0925-2312

VL - 52-54

SP - 169

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JO - Neurocomputing

JF - Neurocomputing

ER -

Electric field modulation of synchronization in neuronal networks

Abstract

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