麻醉导致意识丧失时动态整合/分离平衡的改变

Frontiers in network physiology Pub Date : 2023-12-05 eCollection Date: 2023-01-01 DOI:10.3389/fnetp.2023.1279646
Louis-David Lord, Timoteo Carletti, Henrique Fernandes, Federico E Turkheimer, Paul Expert
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引用次数: 0

摘要

近年来,脑成像研究开始揭示生理上可逆的意识改变状态(如深度睡眠、麻醉和迷幻体验)的神经相关性。正在形成的共识是,正常的清醒意识需要探索一种动态曲目,这种曲目既能实现全局整合,即大脑区域之间的远距离互动,也能实现分离,即在功能特化的集群中进行局部处理。意识状态的改变主要表现为整合/分离的平衡偏离了这一平衡。功能磁共振成像(fMRI)一直是此类研究的首选模式。然而,fMRI 无法以亚秒级的时间分辨率描述整合/分离平衡的特征。在这里,我们研究了在氯胺酮或异丙酚全身麻醉下,猴子(猕猴)的大脑皮层电图(ECoG)数据中的全局脑时空模式。我们首先从整个心电图阵列的特定频带同步角度研究了这些麻醉剂的影响,将单个通道视为振荡器。我们进一步旨在确定,与空间分布的心电图通道子集的同步相比,药物是否会对空间局部振荡器簇内的同步产生不同影响,从而量化生理相关时间尺度上整合/分离平衡的变化。研究结果反映了在氯胺酮和异丙酚麻醉下多个频段的长程整合丧失的全局脑动力学特征,其中以β(13-30 Hz)和低γ频段(30-80 Hz)最为明显,而所有频段的局部同步性都得到了很好的保留。
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Altered dynamical integration/segregation balance during anesthesia-induced loss of consciousness.

In recent years, brain imaging studies have begun to shed light on the neural correlates of physiologically-reversible altered states of consciousness such as deep sleep, anesthesia, and psychedelic experiences. The emerging consensus is that normal waking consciousness requires the exploration of a dynamical repertoire enabling both global integration i.e., long-distance interactions between brain regions, and segregation, i.e., local processing in functionally specialized clusters. Altered states of consciousness have notably been characterized by a tipping of the integration/segregation balance away from this equilibrium. Historically, functional MRI (fMRI) has been the modality of choice for such investigations. However, fMRI does not enable characterization of the integration/segregation balance at sub-second temporal resolution. Here, we investigated global brain spatiotemporal patterns in electrocorticography (ECoG) data of a monkey (Macaca fuscata) under either ketamine or propofol general anesthesia. We first studied the effects of these anesthetics from the perspective of band-specific synchronization across the entire ECoG array, treating individual channels as oscillators. We further aimed to determine whether synchrony within spatially localized clusters of oscillators was differently affected by the drugs in comparison to synchronization over spatially distributed subsets of ECoG channels, thereby quantifying changes in integration/segregation balance on physiologically-relevant time scales. The findings reflect global brain dynamics characterized by a loss of long-range integration in multiple frequency bands under both ketamine and propofol anesthesia, most pronounced in the beta (13-30 Hz) and low-gamma bands (30-80 Hz), and with strongly preserved local synchrony in all bands.

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