评估脑电图（EEG）数据中的瞬态交叉频率耦合。

Assessing transient cross-frequency coupling in EEG data.

作者信息

Cohen Michael X

机构信息

Department of Epileptology and Center for Life and Brain, University of Bonn, Germany.

出版信息

J Neurosci Methods. 2008 Mar 15;168(2):494-9. doi: 10.1016/j.jneumeth.2007.10.012. Epub 2007 Oct 30.

DOI:10.1016/j.jneumeth.2007.10.012

PMID:18061683

Abstract

Synchronization of oscillatory EEG signals across different frequency bands is receiving waxing interest in cognitive neuroscience and neurophysiology, and cross-frequency coupling is being increasingly linked to cognitive and perceptual processes. Several methods exist to examine cross-frequency coupling, although each has its limitations, typically by being flexible only over time or over frequency. Here, a method for assessing transient cross-frequency coupling is presented, which allows one to test for the presence of multiple, dynamic, and flexible cross-frequency coupling structure over both time and frequency. The method is applied to intracranial EEG data, and strong coupling between gamma ( approximately 40-80 Hz) and upper theta ( approximately 7-9 Hz) was observed. This method might have useful applications in uncovering the electrophysiological correlates of cognitive processes.

摘要

不同频段振荡性脑电信号的同步在认知神经科学和神经生理学领域正日益受到关注，并且交叉频率耦合与认知和感知过程的联系也越来越紧密。虽然存在多种方法来检测交叉频率耦合，但每种方法都有其局限性，通常仅在时间或频率上具有灵活性。在此，提出了一种评估瞬态交叉频率耦合的方法，该方法能够在时间和频率上测试多种动态且灵活的交叉频率耦合结构的存在。该方法应用于颅内脑电数据，并观察到伽马波（约40 - 80赫兹）和上θ波（约7 - 9赫兹）之间存在强耦合。这种方法在揭示认知过程的电生理相关性方面可能具有有用的应用。

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评估脑电图（EEG）数据中的瞬态交叉频率耦合。

Assessing transient cross-frequency coupling in EEG data.

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