人类脑电皮质电图中的相位-幅度耦合具有空间分布和相位多样性。
Phase-amplitude coupling in human electrocorticography is spatially distributed and phase diverse.
机构信息
Radboud University Nijmegen, Donders Institute for Brain Cognition and Behaviour, 6525 HR, Nijmegen, The Netherlands.
出版信息
J Neurosci. 2012 Jan 4;32(1):111-23. doi: 10.1523/JNEUROSCI.4816-11.2012.
Abstract
Spatially distributed phase-amplitude coupling (PAC) is a possible mechanism for selectively routing information through neuronal networks. If so, two key properties determine its selectivity and flexibility, phase diversity over space, and frequency diversity. To investigate these issues, we analyzed 42 human electrocorticographic recordings from 27 patients performing a working memory task. We demonstrate that (1) spatially distributed PAC occurred at distances >10 cm, (2) involved diverse preferred coupling phases, and (3) involved diverse frequencies. Using a novel technique [N-way decomposition based on the PARAFAC (for Parallel Factor analysis) model], we demonstrate that (4) these diverse phases originated mainly from the phase-providing oscillations. With these properties, PAC can be the backbone of a mechanism that is able to separate spatially distributed networks operating in parallel.
摘要
空间分布的相位-幅度耦合 (PAC) 可能是一种通过神经元网络有选择地传递信息的机制。如果是这样,两个关键特性决定了其选择性和灵活性,即空间上的相位多样性和频率多样性。为了研究这些问题,我们分析了 27 名患者在执行工作记忆任务时的 42 个人类脑电记录。我们证明了 (1) 空间分布的 PAC 发生在 >10 cm 的距离处,(2) 涉及不同的优先耦合相位,以及 (3) 涉及不同的频率。使用一种新的技术 [基于 PARAFAC(并行因子分析)模型的 N 路分解],我们证明了 (4) 这些不同的相位主要来自提供相位的振荡。具有这些特性,PAC 可以成为一种机制的骨干,该机制能够分离并行工作的空间分布网络。
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