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部分性发作与信号复杂度的早期增加有关。

Partial seizures are associated with early increases in signal complexity.

机构信息

Johns Hopkins University School of Medicine, Department of Neurology - Epilepsy Research Laboratory, Meyer 2-147, 600 N Wolfe Street, Baltimore, MD 21287, USA.

出版信息

Clin Neurophysiol. 2010 Jan;121(1):7-13. doi: 10.1016/j.clinph.2009.09.018. Epub 2009 Nov 11.

DOI:10.1016/j.clinph.2009.09.018
PMID:19910249
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2818227/
Abstract

OBJECTIVES

Partial seizures are often believed to be associated with EEG signals of low complexity because seizures are associated with increased neural network synchrony. The investigations reported here provide an assessment of the signal complexity of epileptic seizure onsets using newly developed quantitative measures.

METHODS

Using the Gabor atom density (GAD) measure of signal complexity, 339 partial seizures in 45 patients with intracranial electrode arrays were analyzed. Segmentation procedures were applied to determine the timing and amplitude of GAD changes relative to the electrographic onset of the seizure.

RESULTS

Three hundred and thirty out of 339 seizures have significant complexity level changes, with 319 (97%) having an increase in complexity. GAD increases occur within seconds of the onset of the partial seizure but are not observed in channels remote from the focus. The complexity increase is similar for seizures from mesial temporal origin, neocortical temporal and extra-temporal origin.

CONCLUSIONS

Partial onset seizures are associated with early increases in signal complexity as measured by GAD. This increase is independent of the location of the seizure focus.

SIGNIFICANCE

Despite the often predominant rhythmic activity that characterizes onset and early evolution of epileptic seizures, partial seizure onset is associated with an early increase in complexity. These changes are common to partial seizures originating from different brain regions, indicating a similar seizure dynamic.

摘要

目的

部分性发作通常被认为与低复杂度的 EEG 信号有关,因为发作与神经网络同步性增加有关。这里报告的研究使用新开发的定量测量方法评估了癫痫发作起始的信号复杂度。

方法

使用信号复杂度的 Gabor 原子密度(GAD)测量,对 45 名颅内电极阵列患者的 339 次部分性发作进行了分析。分段程序用于确定相对于发作的脑电图起始,GAD 变化的时间和幅度。

结果

339 次发作中有 330 次有显著的复杂度水平变化,其中 319 次(97%)复杂度增加。GAD 的增加发生在部分性发作起始后的几秒钟内,但在远离焦点的通道中观察不到。起源于内侧颞叶、皮质颞叶和皮质外的发作的复杂性增加相似。

结论

部分性发作起始与 GAD 测量的信号复杂度早期增加有关。这种增加与发作焦点的位置无关。

意义

尽管常表现为癫痫发作起始和早期演变的主要节律性活动,但部分性发作起始与复杂性的早期增加有关。这些变化在起源于不同脑区的部分性发作中很常见,表明具有相似的发作动态。

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