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在清醒和睡眠中,与运动学习和巩固相关的静息状态下大脑快速和慢速动力学。

Motor learning- and consolidation-related resting state fast and slow brain dynamics across wake and sleep.

机构信息

UR2NF - Neuropsychology and Functional Neuroimaging Research Unit Affiliated at CRCN - Centre for Research in Cognition and Neurosciences, Université Libre de Bruxelles (ULB), Brussels, Belgium.

UNI - ULB Neuroscience Institute, Brussels, Belgium.

出版信息

Sci Rep. 2024 Mar 29;14(1):7531. doi: 10.1038/s41598-024-58123-6.

DOI:10.1038/s41598-024-58123-6
PMID:38553500
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10980824/
Abstract

Motor skills dynamically evolve during practice and after training. Using magnetoencephalography, we investigated the neural dynamics underpinning motor learning and its consolidation in relation to sleep during resting-state periods after the end of learning (boost window, within 30 min) and at delayed time scales (silent 4 h and next day 24 h windows) with intermediate daytime sleep or wakefulness. Resting-state neural dynamics were investigated at fast (sub-second) and slower (supra-second) timescales using Hidden Markov modelling (HMM) and functional connectivity (FC), respectively, and their relationship to motor performance. HMM results show that fast dynamic activities in a Temporal/Sensorimotor state network predict individual motor performance, suggesting a trait-like association between rapidly recurrent neural patterns and motor behaviour. Short, post-training task re-exposure modulated neural network characteristics during the boost but not the silent window. Re-exposure-related induction effects were observed on the next day, to a lesser extent than during the boost window. Daytime naps did not modulate memory consolidation at the behavioural and neural levels. These results emphasise the critical role of the transient boost window in motor learning and memory consolidation and provide further insights into the relationship between the multiscale neural dynamics of brain networks, motor learning, and consolidation.

摘要

运动技能在练习和训练后会动态发展。我们使用脑磁图研究了与睡眠相关的学习后静息状态下(学习结束后的 30 分钟内的促进窗口内)和延迟时间尺度(4 小时静默窗口和次日 24 小时窗口)的运动学习及其巩固的神经动力学,在此期间可以进行中间的日间睡眠或清醒。使用隐马尔可夫模型 (HMM) 和功能连接 (FC) 分别在快速(亚秒)和较慢(超秒)时间尺度上研究静息状态神经动力学,并研究它们与运动表现的关系。HMM 结果表明,在时间/感觉运动状态网络中的快速动态活动预测个体运动表现,这表明快速重复的神经模式与运动行为之间存在特质关联。短暂的训练后任务重新暴露在促进窗口期间但不在静默窗口期间调节神经网络特征。在第二天观察到与重新暴露相关的诱导效应,但程度小于促进窗口。日间小睡并没有调节行为和神经水平上的记忆巩固。这些结果强调了短暂的促进窗口在运动学习和记忆巩固中的关键作用,并进一步深入了解大脑网络的多尺度神经动力学、运动学习和巩固之间的关系。

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本文引用的文献

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Microstructural dynamics of motor learning and sleep-dependent consolidation: A diffusion imaging study.运动学习与睡眠依赖性巩固的微观结构动力学:一项扩散成像研究。
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Does Motor Memory Reactivation through Practice and Post-Learning Sleep Modulate Consolidation?通过练习和学习后睡眠进行的运动记忆再激活是否会调节巩固过程?
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Frequency-specific brain network architecture in resting-state fMRI.
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Human motor sequence learning drives transient changes in network topology and hippocampal connectivity early during memory consolidation.人类运动序列学习在记忆巩固早期驱动网络拓扑和海马连接的瞬时变化。
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Visuomotor Adaptation Modulates the Clustering of Sleep Spindles Into Trains.视运动适应调节睡眠纺锤波聚集成串的过程。
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