Electrical stimulation devices in the treatment of epilepsy

Karceski, Steven

doi:10.1007/978-3-211-33081-4_28

Cited by 5 publications

(1 citation statement)

References 75 publications

(135 reference statements)

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“…In this article, we do not attempt to provide an introduction to epilepsy control2,3,4,5,6, or a historical review and critique of various approaches7. Instead, we identify central challenges in the rational electrical treatment of epilepsy through different lenses summarized by the questions: 1) What are seizures and what does it mean to control them?…”

Section: Introductionmentioning

confidence: 99%

Toward rational design of electrical stimulation strategies for epilepsy control

Sunderam¹,

Gluckman²,

Reato³

et al. 2010

Epilepsy & Behavior

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Electrical stimulation is emerging as a viable alternative for epilepsy patients whose seizures are not alleviated by drugs or surgery. Its attractions are temporal and spatial specificity of action, flexibility of waveform parameters and timing, and the perception that its effects are reversible unlike resective surgery. However, despite significant advances in our understanding of mechanisms of neural electrical stimulation, clinical electrotherapy for seizures relies heavily on empirical tuning of parameters and protocols. We highlight concurrent treatment goals with potentially conflicting design constraints that must be resolved when formulating rational strategies for epilepsy electrotherapy: namely seizure reduction versus cognitive impairment, stimulation efficacy versus tissue safety, and mechanistic insight versus clinical pragmatism. First, treatment markers, objectives, and metrics relevant to electrical stimulation for epilepsy are discussed from a clinical perspective. Then the experimental perspective is presented, with the biophysical mechanisms and modalities of open-loop electrical stimulation, and the potential benefits of closed-loop control for epilepsy.

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Section: Introductionmentioning

confidence: 99%

Toward rational design of electrical stimulation strategies for epilepsy control

Sunderam¹,

Gluckman²,

Reato³

et al. 2010

Epilepsy & Behavior

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Mesoscopic neuron population modeling of normal/epileptic brain dynamics

Myers

Kozma

2017

Cogn Neurodyn

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Simulations of EEG data provide the understanding of how the limbic system exhibits normal and abnormal states of the electrical activity of the brain. While brain activity exhibits a type of homeostasis of excitatory and inhibitory mesoscopic neuron behavior, abnormal neural firings found in the seizure state exhibits brain instability due to runaway oscillatory entrained neural behavior. We utilize a model of mesoscopic brain activity, the KIV model, where each network represents the areas of the limbic system, i.e., hippocampus, sensory cortex, and the amygdala. Our model initially demonstrates oscillatory entrained neural behavior as the epileptogenesis, and then by increasing the external weights that join the three networks that represent the areas of the limbic system, seizure activity entrains the entire system. By introducing an external signal into the model, simulating external electrical titration therapy, the modeled seizure behavior can be 'rebalanced' back to its normal state.

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Neuromodulación quirúrgica. Nuevos horizontes en Neurocirugía

Padrón

2008

Neurocirugía

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Electrical stimulation devices in the treatment of epilepsy

Cited by 5 publications

References 75 publications

Toward rational design of electrical stimulation strategies for epilepsy control

Toward rational design of electrical stimulation strategies for epilepsy control

Mesoscopic neuron population modeling of normal/epileptic brain dynamics

Neuromodulación quirúrgica. Nuevos horizontes en Neurocirugía

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