脑电图与脑磁图联合应用于抗药癫痫的间期尖峰分类

Glykeria Sdoukopoulou, M. Antonakakis, Gabriel Modde, C. Wolters, M. Zervakis
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引用次数: 2

摘要

癫痫是世界上最常见的脑部疾病之一。治疗癫痫的基本原则是当药物不足以抑制癫痫发作时切除致痫区。癫痫伴有间歇尖峰,这是作为癫痫发作标识符的替代标记。由于手动注释需要耗费大量时间,因此对这些峰值的自动时间检测非常重要。脑电和脑磁图(EEG和MEG)是记录大脑活动最常用的测量方式。脑电图和脑磁图是对耐药癫痫进行无创监测的理想方法。对于间隔尖峰的时间检测,已经提出了许多方法。然而,迄今为止只采用单一的测量方式(EEG或MEG),忽略了它们的互补内容。在这项研究中,我们开发了一个多特征和迭代的分类方案,输入来自单一模态(EEG或MEG)或EEG/MEG组合(EMEG)。输入包括统计(峰度和Renyi熵)和谱(能量)特征,以及功能连接指标,来自虚相位滞后指数网络的全局和局部效率。所有模式的分类性能从89%到92.8%不等,其中EMEG的分类性能最高。综上所述,脑电图和脑磁图在间隙峰检测上的互补性是很有前景的,这为癫痫脉冲自动检测方法的发展开辟了新的思路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Interictal Spike Classification in Pharmacoresistant Epilepsy using Combined EEG and MEG
Epilepsy is one of the most common brain disorders worldwide. The basic principle in epilepsy is to resect the epileptogenic zone (EZ) when the medicaments are inadequate to suppress epileptic seizures. Epilepsy is accompanied by interictal spikes, a surrogate marker serving as an identifier of seizures. The automatic temporal detection of these spikes is of major importance due to the demanding time consumption of the manual annotation. Electro- and magneto- encephalography (EEG and MEG) are the most usual measurement modalities for the recording of brain activity. EEG and MEG are ideal modalities for the non-invasive monitoring of drug-resistant epilepsy. Many approaches have been proposed for the temporal detection of interictal spikes. However, only single measurement modality (EEG or MEG) has been used up to now, neglecting their complementary content. In this study, we develop a multi-feature and iterative classification scheme with input from either single modality (EEG or MEG) or combined EEG/MEG (EMEG). The inputs include statistical (kurtosis and Renyi Entropy) and spectral (Energy) features as well as the functional connectivity metrics, global and local efficiency from imaginary phase lag index networks. The classification performance for all modalities ranges from 89% to 92.8%, with the maximum performance being observed for EMEG. Overall, the complementarity of EEG and MEG on the detection of interictal spikes is promising, opening new considerations on the development of automatic epileptic spike detection approaches.
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