Dynamic patterns in a two-dimensional neural field with refractoriness

Qi, Yang; Gong, Pulin

doi:10.1103/physreve.92.022702

Cited by 10 publications

(22 citation statements)

References 47 publications

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“…Here, we focus on the interplay of the cortical propagation and the underlying corticothalamic loop, which is beyond most previous work about spatially extended heterogeneous cortical model, employed to investigate the effect of cortical diffusion on the seizure activity and their transitions as well as transient dynamics [42][43][44][45]. The emergence of breathers in seizure localization has also been explored in previous work, which was discussed in an abstract neural field model with Maxico hat connection profile and also some adaptive feedback, such as spike-frequency adaptation and so on [46][47][48]. Theoretically, the sigmoid function is simplified to a step function, easing linear stability analysis and feasibly employing the Evans function [35,49].…”

Section: Summary and Discussionmentioning

confidence: 99%

“…Their spatiotemporal properties such as spatial extents and temporal 59 frequencies are comparable with experimental observations in humans and rats. The 60 resulting cortical waves have robust frequencies, and their underlying dynamical 61 mechanisms are discovered by employing eigenvalue spectra and corresponding 62 eigenmodes at critical states. Thus we uncover a unified dynamical mechanism for the 63 global and focal aspects of absence epilepsy.…”

Section: Introductionmentioning

confidence: 99%

“…In this work, we have focused on the interplay of cortical propagation and the 454 underlying corticothalamic loop, which goes beyond most previous work about spatially 455 extended heterogeneous but purely cortical models [56][57][58][59]. The emergence of breathers 456 during seizure localization was explored in previous work, but only in an abstract neural 457 field model with Mexican hat connection profile and feedbacks, such as spike-frequency 458 adaptation [42,60,61]. In most previous theoretical work, the sigmoid function was 459 simplified to a step function, easing linear stability analysis [38,62]; however, the step 460 function is unrealistic, whereas our corticothalamic model is physiologically justifiable, 461 and relies on parameters that are experimentally measurable.…”

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confidence: 99%

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Unified Analysis of Global and Focal Aspects of Absence Epilepsy via Neural Field Theory of the Corticothalamic System

Yang

Robinson

2018

Preprint

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A physiology-based corticothalamic model is investigated with focal spatial heterogeneity, to unify global and focal aspects of absence epilepsy. Numerical and analytical calculations are employed to investigate the emergent spatiotemporal dynamics induced by focal activity as well as their underlying dynamical mechanisms. The spatiotemporal dynamics can be categorized into three scenarios: suppression, localization, and generalization of the focal activity, as summarized from a phase diagram vs. focal width and characteristic axon range. The corresponding temporal frequencies and spatial extents of wave activity during seizure generalization and localization agree well with experimental observations of global and focal aspects of absence epilepsy, respectively. The emergent seizure localization provide a biophysical explanation of the temporally higher frequency but spatially more localized cortical waves observed in genetic rat models that display characteristics of human absence epilepsy. Predictions are also presented for further experimental test. Author SummaryAbsence epilepsy is characterized by a sudden paroxysmal loss of consciousness accompanied by oscillatory activity propagating over many brain areas. Although primary generalized absence seizures are supported by the global corticothalamic system, converging experimental evidence supports a focal theory of absence epilepsy. Here we propose a dynamical mechanism to unify the global and focal aspects of absence epilepsy, with focal absence seizures associated with seizure localization, and the global ones associated with seizure generalization. Our corticothalamic model is used to investigate how seizure rhythms and spatial extents are related in these two different aspects of absence epilepsy. The results account for the difference of the experimentally observed seizure rhythms and spatial extents between humans and genetic rat models, which has previously been used to argue against the validity of such rats as animal models of absence epilepsy in humans.

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Section: Summary and Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

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Unified Analysis of Global and Focal Aspects of Absence Epilepsy via Neural Field Theory of the Corticothalamic System

Yang

Robinson

2018

Preprint

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“…Numerical Bifurcation Analysis. Gong and Robinson [36], and Qi and Gong [62] found wandering spots and propagating ensembles using direct numerical simulations on the plane. Here, we perform a numerical bifurcation analysis with various control parameters for the structures found in Section 3 on a one-dimensional domain.…”

Section: Tw Mb Bmentioning

confidence: 99%

“…Further simulation shows that the model also supports coherent states in the form of stochastic travelling waves. In two spatial dimensions, the system is known to support travelling spots [36,62]. In Figure 4, we show a time simulation of the stochastic model with initial condition…”

Section: Travelling Wavesmentioning

confidence: 99%

Macroscopic coherent structures in a stochastic neural network: from interface dynamics to coarse-grained bifurcation analysis

Avitabile

Wedgwood

2016

Preprint

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We study coarse pattern formation in a cellular automaton modelling a spatially-extended stochastic neural network. The model, originally proposed by Gong and Robinson (Phys Rev E 85(5):055,101(R), 2012), is known to support stationary and travelling bumps of localised activity. We pose the model on a ring and study the existence and stability of these patterns in various limits using a combination of analytical and numerical techniques. In a purely deterministic version of the model, posed on a continuum, we construct bumps and travelling waves analytically using standard interface methods from neural field theory. In a stochastic version with Heaviside firing rate, we construct approximate analytical probability mass functions associated with bumps and travelling waves. In the full stochastic model posed on a discrete lattice, where a coarse analytic description is unavailable, we compute patterns and their linear stability using equation-free methods. The lifting procedure used in the coarse time-stepper is informed by the analysis in the deterministic and stochastic limits. In all settings, we identify the synaptic profile as a mesoscopic variable, and the width of the corresponding activity set as a macroscopic variable. Stationary and travelling bumps have similar meso-and macroscopic profiles, but different microscopic structure, hence we propose lifting operators which use microscopic motifs to disambiguate them. We provide numerical evidence that waves are supported by a combination of

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Macroscopic coherent structures in a stochastic neural network: from interface dynamics to coarse-grained bifurcation analysis

Avitable

Wedgwood

2017

J. Math. Biol.

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We study coarse pattern formation in a cellular automaton modelling a spatially-extended stochastic neural network. The model, originally proposed by Gong and Robinson (Phys Rev E 85(5):055,101(R), 2012), is known to support stationary and travelling bumps of localised activity. We pose the model on a ring and study the existence and stability of these patterns in various limits using a combination of analytical and numerical techniques. In a purely deterministic version of the model, posed on a continuum, we construct bumps and travelling waves analytically using standard interface methods from neural field theory. In a stochastic version with Heaviside firing rate, we construct approximate analytical probability mass functions associated with bumps and travelling waves. In the full stochastic model posed on a discrete lattice, where a coarse analytic description is unavailable, we compute patterns and their linear stability using equation-free methods. The lifting procedure used in the coarse time-stepper is informed by the analysis in the deterministic and stochastic limits. In all settings, we identify the synaptic profile as a mesoscopic variable, and the width of the corresponding activity set as a macroscopic variable. Stationary and travelling bumps have similar meso- and macroscopic profiles, but different microscopic structure, hence we propose lifting operators which use microscopic motifs to disambiguate them. We provide numerical evidence that waves are supported by a combination of high synaptic gain and long refractory times, while meandering bumps are elicited by short refractory times.

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Dynamic patterns in a two-dimensional neural field with refractoriness

Cited by 10 publications

References 47 publications

Unified Analysis of Global and Focal Aspects of Absence Epilepsy via Neural Field Theory of the Corticothalamic System

Unified Analysis of Global and Focal Aspects of Absence Epilepsy via Neural Field Theory of the Corticothalamic System

Macroscopic coherent structures in a stochastic neural network: from interface dynamics to coarse-grained bifurcation analysis

Macroscopic coherent structures in a stochastic neural network: from interface dynamics to coarse-grained bifurcation analysis

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