Yu Mengxia, Song Haoming, Huang Jialin, Song Yiying, Liu Jia
Bilingual Cognition and Development Laboratory, Center for Linguistics and Applied Linguistics, Guangdong University of Foreign Studies, Guangzhou, China.
State Key Laboratory of Cognitive Neuroscience and Learning, IDG/McGovern Institute for Brain Research, Beijing Normal University, Beijing, China.
Front Hum Neurosci. 2020 Nov 16;14:571733. doi: 10.3389/fnhum.2020.571733. eCollection 2020.
Repeated practice is fundamental to the acquisition of skills, which is typically accompanied by increasing reliability of neural representations that manifested as more stable activation patterns for the trained stimuli. However, large-scale neural pattern induced by learning has been rarely studied. Here, we investigated whether global connectivity patterns became more reliable as a result of motor learning using a novel analysis of the multivariate pattern of functional connectivity (MVPC). Human participants were trained with a finger-tapping motor task for five consecutive days and went through Functional magnetic resonance imaging (fMRI) scanning before and after training. We found that motor learning increased the whole-brain MVPC stability of the primary motor cortex (M1) when participants performed the trained sequence, while no similar effects were observed for the untrained sequence. Moreover, the increase of MVPC stability correlated with participants' improvement in behavioral performance. These findings suggested that the acquisition of motor skills was supported by the increased connectivity pattern stability between the M1 and the rest of the brain. In summary, our study not only suggests global neural pattern stabilization as a neural signature for effective learning but also advocates applying the MVPC analysis to reveal mechanisms of distributed network reorganization supporting various types of learning.
反复练习是技能习得的基础,在此过程中,神经表征的可靠性通常会不断提高,表现为对训练刺激的激活模式更加稳定。然而,由学习引起的大规模神经模式却很少被研究。在这里,我们使用一种新颖的功能连接多元模式(MVPC)分析方法,研究了运动学习是否会使全局连接模式变得更加可靠。人类参与者连续五天接受手指敲击运动任务训练,并在训练前后进行功能磁共振成像(fMRI)扫描。我们发现,当参与者执行训练序列时,运动学习提高了初级运动皮层(M1)的全脑MVPC稳定性,而对于未训练序列则未观察到类似效果。此外,MVPC稳定性的增加与参与者行为表现的改善相关。这些发现表明,M1与大脑其他区域之间连接模式稳定性的增加支持了运动技能的习得。总之,我们的研究不仅表明全局神经模式稳定是有效学习的神经标志,还提倡应用MVPC分析来揭示支持各种类型学习的分布式网络重组机制。
