Combined Effects of Feedforward Inhibition and Excitation in Thalamocortical Circuit on the Transitions of Epileptic Seizures

Fan, Denggui; Duan, Lixia; Wang, Qian; Luan, Guoming

doi:10.3389/fncom.2017.00059

Cited by 12 publications

(8 citation statements)

References 59 publications

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“…(1)) of absence epilepsy by using bifurcation analysis. In order to understand the mechanisms of absence seizures including SWDs, many studies have been conducted on how the model parameters affect the states and their transitions of the system, such as the input constant parameter 61 , direct PY-to-TC excitation c te and feedforward TC-to-PY inhibition c et 62 , and the feedforward inhibition and excitation from TC to cortex 63 . Motivated by the recent experimental results about the bidirectional communications of absence seizures in thalamocortical circuit 32,54,55 , we here focus on the top-down PY-to-TC excitation c te and the feedforward RE-to-TC inhibition c tr .…”

Section: Discussionmentioning

confidence: 99%

“…It will also be a big challenge to perform integrated qualitative and quantitative analyses of a multi-level computational model of epilepsy that reproduces various brain activities. Second, there are also many paths regulating the genesis and evolution of seizures in the cortico-thalamo-cortical loops 45,46,63,73–75 , and we have only investigated mechanisms of the top-town PY-to-TC excitation and feedforward RE-to-TC inhibition. The next step study would consider more comprehensive dynamical and physiological mechanisms of epileptic seizures with multiple changing parameters, and also other target brain regions for seizure control 45,46 .…”

Section: Discussionmentioning

confidence: 99%

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Robust closed-loop control of spike-and-wave discharges in a thalamocortical computational model of absence epilepsy

Cao

et al. 2019

Sci Rep

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In this paper, we investigate the abatement of spike-and-wave discharges in a thalamocortical model using a closed-loop brain stimulation method. We first explore the complex states and various transitions in the thalamocortical computational model of absence epilepsy by using bifurcation analysis. We demonstrate that the Hopf and double cycle bifurcations are the key dynamical mechanisms of the experimental observed bidirectional communications during absence seizures through top-down cortical excitation and thalamic feedforward inhibition. Then, we formulate the abatement of epileptic seizures to a closed-loop tracking control problem. Finally, we propose a neural network based sliding mode feedback control system to drive the dynamics of pathological cortical area to track the desired normal background activities. The control system is robust to uncertainties and disturbances, and its stability is guaranteed by Lyapunov stability theorem. Our results suggest that the seizure abatement can be modeled as a tracking control problem and solved by a robust closed-loop control method, which provides a promising brain stimulation strategy.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Robust closed-loop control of spike-and-wave discharges in a thalamocortical computational model of absence epilepsy

Cao

et al. 2019

Sci Rep

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“…As one of the representatives of the neural field model, Taylor model can perfectly simulate the 2-4 Hz SWD that characterizes absence seizures [37,38]. Recently, scholars have proposed many improved models to study absence epilepsy [39,40]. For examples, Fan et al investigated the combined effects of feedforward inhibition and excitation in thalamocortical circuit on the transition behaviors of epileptic seizures by introducing the feedforward excitation from thalamic relay nucleus to excitatory pyramidal neuronal into the thalamocortical network [39].…”

Section: Introductionmentioning

confidence: 99%

“…Recently, scholars have proposed many improved models to study absence epilepsy [39,40]. For examples, Fan et al investigated the combined effects of feedforward inhibition and excitation in thalamocortical circuit on the transition behaviors of epileptic seizures by introducing the feedforward excitation from thalamic relay nucleus to excitatory pyramidal neuronal into the thalamocortical network [39]. Liu et al constructed another modified thalamocortical network by considering a disinhibition neural population [40].…”

Section: Introductionmentioning

confidence: 99%

“…Beverlin et al showed that feedforward inhibition from thalamic relay nucleus (TC) to inhibitory interneuron has even more stronger functions on the cortex than the feedforward excitation from TC to excitatory pyramidal neuronal (PY) [46]. To the best of our knowledge, although Fan et al and Liu et al had considered the above-mentioned physiological phenomena in their computational models separately [39,40], no scholars have considered these two facts at the same time. Motivated by these, we propose a more comprehensive model to systematically investigate the effects of important model parameters on the transition behaviors of epileptic seizures including tonic-clonic and absence seizures.…”

Section: Introductionmentioning

confidence: 99%

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Dynamic Transitions of Epilepsy Waveforms Induced by Astrocyte Dysfunction and Electrical Stimulation

et al. 2020

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Experimental studies have shown that astrocytes participate in epilepsy through inducing the release of glutamate. Meanwhile, considering the disinhibition circuit among inhibitory neuronal populations with different time scales and the feedforward inhibition connection from thalamic relay nucleus to cortical inhibitory neuronal population, here, we propose a modified thalamocortical field model to systematically investigate the mechanism of epilepsy. Firstly, our results show that rich firing activities can be induced by astrocyte dysfunction, including high or low saturated state, high- or low-frequency clonic, spike-wave discharge (SWD), and tonic. More importantly, with the enhancement of feedforward inhibition connection, SWD and tonic oscillations will disappear. In other words, all these pathological waveforms can be suppressed or eliminated. Then, we explore the control effects after different external stimulations applying to thalamic neuronal population. We find that single-pulse stimulation can not only suppress but also induce pathological firing patterns, such as SWD, tonic, and clonic oscillations. And we further verify that deep brain stimulation can control absence epilepsy by regulating the amplitude and pulse width of stimulation. In addition, based on our modified model, 3 : 2 coordinated reset stimulation strategies with different intensities are compared and a more effective and safer stimulation mode is proposed. Our conclusions are expected to give more theoretical insights into the treatment of epilepsy.

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The dynamical role of electromagnetic induction in epileptic seizures: a double-edged sword

Zhao

Wang

2021

Nonlinear Dyn

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Combined Effects of Feedforward Inhibition and Excitation in Thalamocortical Circuit on the Transitions of Epileptic Seizures

Cited by 12 publications

References 59 publications

Robust closed-loop control of spike-and-wave discharges in a thalamocortical computational model of absence epilepsy

Robust closed-loop control of spike-and-wave discharges in a thalamocortical computational model of absence epilepsy

Dynamic Transitions of Epilepsy Waveforms Induced by Astrocyte Dysfunction and Electrical Stimulation

The dynamical role of electromagnetic induction in epileptic seizures: a double-edged sword

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