A Stable EEG Epilepsy Network Spans From Infraslow to Ripple and From Interictal to Ictus.

IF 2.3 4区医学 Q3 CLINICAL NEUROLOGY

Journal of Clinical Neurophysiology Pub Date : 2024-03-01 Epub Date: 2022-10-03 DOI:10.1097/WNP.0000000000000971

Sushma Ghimire, Mukesh Dhamala, Charles M Epstein

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引用次数: 0

Abstract

Purpose: To characterize the epilepsy network as reflected in intracranial electroencephalography (iEEG) across the full spectrum of iEEG frequencies and different phases of epilepsy, using a single, conceptually straightforward mathematical measure.

Methods: The authors applied the spectral Granger causality techniques to intracranial electroencephalography recordings and computed contact-by-contact inward, outward, and total causal flow across frequencies and seizure phases in a selected group of three patients with well-defined, nonlesional seizure foci and prolonged responses to invasive procedures. One seizure and one interictal sample were analyzed per subject.

Results: A prominent intracranial electroencephalography network was identified by Granger causality at both high and low frequencies. This network persists during the preictal and interictal phases of epilepsy and closely matches the visible seizure onset. The causal inflow network corresponded to seizure onset electrode contacts in 8 of 12 conditions, including ripple, infraslow, preictal, and interictal phases of epilepsy. Its most striking feature is the consistent dominance of causal inflow rather than outflow in the vicinity of the seizure onset zone.

Conclusions: Findings of this study indicate that a stable intracranial electroencephalography epilepsy network persists, and it can be characterized by a single Granger causality measure from infraslow to ripple frequencies and from the interictal to the immediate preictal phases of epilepsy.

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一个稳定的脑电图癫痫网络跨越了 "下流 "到 "波纹 "和 "发作间期 "到 "间歇期"。

目的：使用概念简单明了的单一数学测量方法，描述颅内脑电图（iEEG）所反映的癫痫网络在整个 iEEG 频率频谱和癫痫不同阶段的特征：作者将频谱格兰杰因果关系技术应用于颅内脑电图记录，并计算了三组经过挑选的患者在不同频率和发作阶段的逐次接触向内、向外和总因果流，这三组患者均有明确定义的非发作性癫痫病灶，且对侵入性程序的反应时间较长。每个受试者分析一次发作和一次发作间期样本：结果：通过高频和低频的格兰杰因果关系确定了一个突出的颅内脑电图网络。该网络在癫痫发作前和发作间期持续存在，并与可见的癫痫发作起始点密切吻合。在 12 种情况中，有 8 种情况下的因果流入网络与癫痫发作电极接触点相对应，包括癫痫的波纹期、次低期、发作前和发作间期。其最显著的特征是，在癫痫发作起始区附近，因果流入始终占据主导地位，而不是流出：本研究的结果表明，颅内脑电图癫痫网络是稳定的，从癫痫的次低频到波纹频率，以及从发作间期到发作前即刻阶段，都可以用单一的格兰杰因果关系来描述。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Clinical Neurophysiology 医学-临床神经学

CiteScore

4.60

自引率

4.20%

发文量

198

审稿时长

6-12 weeks

期刊介绍： The Journal of Clinical Neurophysiology features both topical reviews and original research in both central and peripheral neurophysiology, as related to patient evaluation and treatment. Official Journal of the American Clinical Neurophysiology Society.