Impact of biological rhythms on the importance hierarchy of constituents in time-dependent functional brain networks.

Timo Bröhl, Randi von Wrede, Klaus Lehnertz
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Abstract

Biological rhythms are natural, endogenous cycles with period lengths ranging from less than 24 h (ultradian rhythms) to more than 24 h (infradian rhythms). The impact of the circadian rhythm (approximately 24 h) and ultradian rhythms on spectral characteristics of electroencephalographic (EEG) signals has been investigated for more than half a century. Yet, only little is known on how biological rhythms influence the properties of EEG-derived evolving functional brain networks. Here, we derive such networks from multiday, multichannel EEG recordings and use different centrality concepts to assess the time-varying importance hierarchy of the networks' vertices and edges as well as the various aspects of their structural integration in the network. We observe strong circadian and ultradian influences that highlight distinct subnetworks in the evolving functional brain networks. Our findings indicate the existence of a vital and fundamental subnetwork that is rather generally involved in ongoing brain activities during wakefulness and sleep.

Abstract Image

Abstract Image

Abstract Image

生物节律对时间依赖功能脑网络中成分重要性层次的影响。
生物节律是自然的内源性周期,周期长度从小于24小时(超昼夜节律)到大于24小时(次昼夜节律)不等。半个多世纪以来,人们一直在研究昼夜节律(约24小时)和超昼夜节律对脑电图信号频谱特征的影响。然而,对于生物节律如何影响脑电图衍生的进化功能脑网络的特性,人们知之甚少。在这里,我们从多日、多通道的脑电图记录中推导出这样的网络,并使用不同的中心性概念来评估网络顶点和边缘的时变重要性层次,以及它们在网络中结构集成的各个方面。我们观察到强烈的昼夜节律和超昼夜影响,突出了进化功能脑网络中不同的子网络。我们的研究结果表明,在清醒和睡眠期间,存在一个重要而基本的子网络,它通常参与正在进行的大脑活动。
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CiteScore
2.70
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