Dynamic networks of cortico-muscular interactions in sleep and neurodegenerative disorders.

Frontiers in network physiology Pub Date : 2023-09-05 eCollection Date: 2023-01-01 DOI:10.3389/fnetp.2023.1168677
Rossella Rizzo, Jilin W J L Wang, Anna DePold Hohler, James W Holsapple, Okeanis E Vaou, Plamen Ch Ivanov
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Abstract

The brain plays central role in regulating physiological systems, including the skeleto-muscular and locomotor system. Studies of cortico-muscular coordination have primarily focused on associations between movement tasks and dynamics of specific brain waves. However, the brain-muscle functional networks of synchronous coordination among brain waves and muscle activity rhythms that underlie locomotor control remain unknown. Here we address the following fundamental questions: what are the structure and dynamics of cortico-muscular networks; whether specific brain waves are main network mediators in locomotor control; how the hierarchical network organization relates to distinct physiological states under autonomic regulation such as wake, sleep, sleep stages; and how network dynamics are altered with neurodegenerative disorders. We study the interactions between all physiologically relevant brain waves across cortical locations with distinct rhythms in leg and chin muscle activity in healthy and Parkinson's disease (PD) subjects. Utilizing Network Physiology framework and time delay stability approach, we find that 1) each physiological state is characterized by a unique network of cortico-muscular interactions with specific hierarchical organization and profile of links strength; 2) particular brain waves play role as main mediators in cortico-muscular interactions during each state; 3) PD leads to muscle-specific breakdown of cortico-muscular networks, altering the sleep-stage stratification pattern in network connectivity and links strength. In healthy subjects cortico-muscular networks exhibit a pronounced stratification with stronger links during wake and light sleep, and weaker links during REM and deep sleep. In contrast, network interactions reorganize in PD with decline in connectivity and links strength during wake and non-REM sleep, and increase during REM, leading to markedly different stratification with gradual decline in network links strength from wake to REM, light and deep sleep. Further, we find that wake and sleep stages are characterized by specific links strength profiles, which are altered with PD, indicating disruption in the synchronous activity and network communication among brain waves and muscle rhythms. Our findings demonstrate the presence of previously unrecognized functional networks and basic principles of brain control of locomotion, with potential clinical implications for novel network-based biomarkers for early detection of Parkinson's and neurodegenerative disorders, movement, and sleep disorders.

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睡眠和神经退行性疾病中皮质-肌肉相互作用的动态网络。
大脑在调节生理系统中起着核心作用,包括骨骼肌和运动系统。皮质-肌肉协调的研究主要集中在运动任务和特定脑电波动力学之间的关联上。然而,作为运动控制基础的脑电波和肌肉活动节奏之间同步协调的脑肌肉功能网络仍然未知。在这里,我们解决了以下基本问题:皮质肌网络的结构和动力学是什么;特定的脑电波是否是运动控制中的主要网络介质;分层网络组织如何与自主调节下的不同生理状态相关,如觉醒、睡眠、睡眠阶段;以及神经退行性疾病如何改变网络动力学。我们研究了健康和帕金森病(PD)受试者腿部和下巴肌肉活动具有不同节奏的皮层位置的所有生理相关脑电波之间的相互作用。利用网络生理学框架和时延稳定性方法,我们发现:1)每种生理状态都由一个独特的皮层-肌肉相互作用网络表征,该网络具有特定的层次组织和链路强度分布;2) 在每种状态下,特定的脑电波在皮质-肌肉相互作用中起着主要介质的作用;3) PD导致皮质-肌肉网络的肌肉特异性破坏,改变网络连接和连接强度的睡眠阶段分层模式。在健康受试者中,皮质-肌肉网络表现出明显的分层,在清醒和轻度睡眠期间具有更强的联系,在快速眼动和深度睡眠期间具有较弱的联系。相反,PD中的网络相互作用在觉醒和非REM睡眠期间重组,连接和连接强度下降,在REM期间增加,导致明显不同的分层,从觉醒到REM、轻度和深度睡眠,网络连接强度逐渐下降。此外,我们发现,觉醒和睡眠阶段的特征是特定的联系强度特征,这些特征随着PD而改变,表明脑电波和肌肉节律之间的同步活动和网络通信中断。我们的发现证明了以前未被识别的功能网络和大脑运动控制的基本原理的存在,对早期检测帕金森氏症和神经退行性疾病、运动和睡眠障碍的新型网络生物标志物具有潜在的临床意义。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
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