Modeling focal epileptic activity in the Wilson-Cowan model with depolarization block

Hil G.E. Meijer; Tahra L. Eissa; Bert Kiewiet; Jeremy F. Neuman; Catherine A. Schevon; Ronald G. Emerson; Robert R. Goodman; Guy M. McKhann; Charles J. Marcuccilli; Andrew K. Tryba; Jack D. Cowan; Stephan A. van Gils; Wim van Drongelen

doi:10.1186/s13408-015-0019-4

Modeling focal epileptic activity in the Wilson-Cowan model with depolarization block

Hil G.E. Meijer, Tahra L. Eissa, Bert Kiewiet, Jeremy F. Neuman, Catherine A. Schevon, Ronald G. Emerson, Robert R. Goodman, Guy M. McKhann, Charles J. Marcuccilli, Andrew K. Tryba, Jack D. Cowan, Stephan A. van Gils, Wim van Drongelen

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40 Scopus citations

Abstract

Measurements of neuronal signals during human seizure activity and evoked epileptic activity in experimental models suggest that, in these pathological states, the individual nerve cells experience an activity driven depolarization block, i.e. they saturate. We examined the effect of such a saturation in the Wilson-Cowan formalism by adapting the nonlinear activation function; we substituted the commonly applied sigmoid for a Gaussian function. We discuss experimental recordings during a seizure that support this substitution. Next we perform a bifurcation analysis on the Wilson-Cowan model with a Gaussian activation function. The main effect is an additional stable equilibrium with high excitatory and low inhibitory activity. Analysis of coupled local networks then shows that such high activity can stay localized or spread. Specifically, in a spatial continuum we show a wavefront withinhibition leading followed by excitatory activity.We relate our model simulations to observations of spreading activity during seizures.

Original language	English
Article number	7
Journal	Journal of Mathematical Neuroscience
Volume	5
Issue number	1
DOIs	https://doi.org/10.1186/s13408-015-0019-4
State	Published - 2015
Externally published	Yes

Keywords

Activation function
Bifurcation analysis
Depolarization block
Focal epilepsy

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10.1186/s13408-015-0019-4

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Meijer, H. G. E., Eissa, T. L., Kiewiet, B., Neuman, J. F., Schevon, C. A., Emerson, R. G., Goodman, R. R., McKhann, G. M., Marcuccilli, C. J., Tryba, A. K., Cowan, J. D., van Gils, S. A., & van Drongelen, W. (2015). Modeling focal epileptic activity in the Wilson-Cowan model with depolarization block. Journal of Mathematical Neuroscience, 5(1), Article 7. https://doi.org/10.1186/s13408-015-0019-4

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title = "Modeling focal epileptic activity in the Wilson-Cowan model with depolarization block",

abstract = "Measurements of neuronal signals during human seizure activity and evoked epileptic activity in experimental models suggest that, in these pathological states, the individual nerve cells experience an activity driven depolarization block, i.e. they saturate. We examined the effect of such a saturation in the Wilson-Cowan formalism by adapting the nonlinear activation function; we substituted the commonly applied sigmoid for a Gaussian function. We discuss experimental recordings during a seizure that support this substitution. Next we perform a bifurcation analysis on the Wilson-Cowan model with a Gaussian activation function. The main effect is an additional stable equilibrium with high excitatory and low inhibitory activity. Analysis of coupled local networks then shows that such high activity can stay localized or spread. Specifically, in a spatial continuum we show a wavefront withinhibition leading followed by excitatory activity.We relate our model simulations to observations of spreading activity during seizures.",

keywords = "Activation function, Bifurcation analysis, Depolarization block, Focal epilepsy",

author = "Meijer, {Hil G.E.} and Eissa, {Tahra L.} and Bert Kiewiet and Neuman, {Jeremy F.} and Schevon, {Catherine A.} and Emerson, {Ronald G.} and Goodman, {Robert R.} and McKhann, {Guy M.} and Marcuccilli, {Charles J.} and Tryba, {Andrew K.} and Cowan, {Jack D.} and {van Gils}, {Stephan A.} and {van Drongelen}, Wim",

note = "Publisher Copyright: {\textcopyright} 2015 Meijer et al.",

year = "2015",

doi = "10.1186/s13408-015-0019-4",

language = "English",

volume = "5",

journal = "Journal of Mathematical Neuroscience",

issn = "2190-8567",

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TY - JOUR

T1 - Modeling focal epileptic activity in the Wilson-Cowan model with depolarization block

AU - Meijer, Hil G.E.

AU - Eissa, Tahra L.

AU - Kiewiet, Bert

AU - Neuman, Jeremy F.

AU - Schevon, Catherine A.

AU - Emerson, Ronald G.

AU - Goodman, Robert R.

AU - McKhann, Guy M.

AU - Marcuccilli, Charles J.

AU - Tryba, Andrew K.

AU - Cowan, Jack D.

AU - van Gils, Stephan A.

AU - van Drongelen, Wim

PY - 2015

Y1 - 2015

N2 - Measurements of neuronal signals during human seizure activity and evoked epileptic activity in experimental models suggest that, in these pathological states, the individual nerve cells experience an activity driven depolarization block, i.e. they saturate. We examined the effect of such a saturation in the Wilson-Cowan formalism by adapting the nonlinear activation function; we substituted the commonly applied sigmoid for a Gaussian function. We discuss experimental recordings during a seizure that support this substitution. Next we perform a bifurcation analysis on the Wilson-Cowan model with a Gaussian activation function. The main effect is an additional stable equilibrium with high excitatory and low inhibitory activity. Analysis of coupled local networks then shows that such high activity can stay localized or spread. Specifically, in a spatial continuum we show a wavefront withinhibition leading followed by excitatory activity.We relate our model simulations to observations of spreading activity during seizures.

AB - Measurements of neuronal signals during human seizure activity and evoked epileptic activity in experimental models suggest that, in these pathological states, the individual nerve cells experience an activity driven depolarization block, i.e. they saturate. We examined the effect of such a saturation in the Wilson-Cowan formalism by adapting the nonlinear activation function; we substituted the commonly applied sigmoid for a Gaussian function. We discuss experimental recordings during a seizure that support this substitution. Next we perform a bifurcation analysis on the Wilson-Cowan model with a Gaussian activation function. The main effect is an additional stable equilibrium with high excitatory and low inhibitory activity. Analysis of coupled local networks then shows that such high activity can stay localized or spread. Specifically, in a spatial continuum we show a wavefront withinhibition leading followed by excitatory activity.We relate our model simulations to observations of spreading activity during seizures.

KW - Activation function

KW - Bifurcation analysis

KW - Depolarization block

KW - Focal epilepsy

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U2 - 10.1186/s13408-015-0019-4

DO - 10.1186/s13408-015-0019-4

M3 - Article

AN - SCOPUS:84983440635

SN - 2190-8567

VL - 5

JO - Journal of Mathematical Neuroscience

JF - Journal of Mathematical Neuroscience

IS - 1

M1 - 7

ER -

Modeling focal epileptic activity in the Wilson-Cowan model with depolarization block

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Keywords

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