视觉运动学习对大脑功能连接影响的纵向研究。

Psychophysiology Pub Date : 2024-05-01 Epub Date: 2023-12-30 DOI:10.1111/psyp.14510
Kuo-Pin Wang, Chien-Lin Yu, Cheng Shen, Thomas Schack, Tsung-Min Hung
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引用次数: 0

摘要

前顶叶和运动皮层-感觉运动回路的神经适应对于视觉运动技能的习得至关重要。然而,在视觉运动技能习得过程中,这些回路中高度动态神经连接的具体性质仍不清楚。为了更全面地了解视觉运动技能的习得与神经连接之间的关系,我们使用脑电相干性来捕捉神经连接的高度动态性。我们招募了 60 名男性新手,将他们随机分配到实验组(EG)或对照组(CG)。实验组的参与者被要求反复进行推杆练习,而对照组的参与者则不进行高尔夫练习。此外,我们还使用 8-13 Hz 的假想相位相干分析了在高尔夫推杆任务中顶叶前部网络(Fz-P3 和 Fz-P4)和运动皮层-感觉运动网络(Cz-C3 和 Cz-C4)的连接性。为了深入了解学习轨迹的动态性质,我们比较了三个时间点的数据:基线(T1)、比基线提高 50%(T2)和比基线提高 100%(T3)。结果主要集中在 EG 上,观察到左侧运动皮层-感觉运动回路的连通性呈倒 U 型连贯曲线,而右侧顶叶前部回路的连通性从 T2 到 T3 呈上升趋势。这些结果表明,皮层与皮层之间的动态交流,尤其是涉及左侧运动皮层-感觉运动回路和额叶-左顶叶回路的交流。此外,我们的研究结果部分支持了 Hikosaka 等人的模型,并对这些回路在视觉运动学习中的具体作用提供了更多的见解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A longitudinal study of the effect of visuomotor learning on functional brain connectivity.

Neural adaptation in the frontoparietal and motor cortex-sensorimotor circuits is crucial for acquiring visuomotor skills. However, the specific nature of highly dynamic neural connectivity in these circuits during the acquisition of visuomotor skills remains unclear. To achieve a more comprehensive understanding of the relationship between acquisition of visuomotor skills and neural connectivity, we used electroencephalographic coherence to capture highly dynamic nature of neural connectivity. We recruited 60 male novices who were randomly assigned to either the experimental group (EG) or the control group (CG). Participants in EG were asked to engage in repeated putting practice, but CG did not engage in golf practice. In addition, we analyzed the connectivity by using 8-13 Hz imaginary inter-site phase coherence in the frontoparietal networks (Fz-P3 and Fz-P4) and the motor cortex-sensorimotor networks (Cz-C3 and Cz-C4) during a golf putting task. To gain a deeper understanding of the dynamic nature of learning trajectories, we compared data at three time points: baseline (T1), 50% improvement from baseline (T2), and 100% improvement from baseline (T3). The results primarily focused on EG, an inverted U-shaped coherence curve was observed in the connectivity of the left motor cortex-sensorimotor circuit, whereas an increase in the connectivity of the right frontoparietal circuit from T2 to T3 was revealed. These results imply that the dynamics of cortico-cortical communication, particularly involving the left motor cortex-sensorimotor and frontal-left parietal circuits. In addition, our findings partially support Hikosaka et al.'s model and provide additional insight into the specific role of these circuits in visuomotor learning.

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