Working memory load increases movement-related alpha and beta desynchronization

IF 2 3区心理学 Q3 BEHAVIORAL SCIENCES

Neuropsychologia Pub Date : 2024-10-31 DOI:10.1016/j.neuropsychologia.2024.109030

Aoki Takahashi , Shugo Iuchi , Taisei Sasaki , Yuhei Hashimoto , Riku Ishizaka , Kodai Minami , Tatsunori Watanabe

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引用次数: 0

Abstract

Working memory (WM) load has been well-documented to impair selective attention and inhibitory control. However, its effects on motor function remain insufficiently explored. To extend the existing literature, we investigated the impact of WM load on force control and movement-related brain activity. Sixteen healthy young participants performed a visual static force matching task using a pinch grip under varying WM loads. The task included low and high WM load conditions (memorizing one digit or six digits), and the precision level required to control force was adjusted by manipulating visual gain (low vs. high visual gains), with higher visual gain necessitating more precise force control. Peri-movement alpha and beta event-related desynchronization (ERD), along with force accuracy and steadiness, were measured using electroencephalography recorded over the central areas during the force control task. Results indicated that while force accuracy and steadiness significantly improved with higher visual gain, there was no significant effect of WM load on these measures. Alpha and beta ERD were greater under high than low visual gain, and also greater under high than low WM load. These findings suggest that in young adults, increased WM load leads to compensatory increases in sensorimotor cortical activity to mitigate potential declines in static force control performance that may result from the depletion of neural resources caused by WM load. Our findings extend current understanding of the interaction between WM and sensorimotor processes by offering new insights into how movement-related brain activity is influenced by heightened WM load.

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工作记忆负荷会增加与运动相关的阿尔法和贝塔非同步化。

工作记忆（WM）负荷会损害选择性注意和抑制控制，这一点已得到充分证实。然而，其对运动功能的影响仍未得到充分探讨。为了扩展现有文献，我们研究了工作记忆负荷对力控制和运动相关大脑活动的影响。16 名健康的年轻参与者在不同的 WM 负荷下使用捏握完成了一项视觉静态力匹配任务。该任务包括低和高 WM 负荷条件（记忆一位数字或六位数字），通过操纵视觉增益（低视觉增益与高视觉增益）来调整力控制所需的精确度，视觉增益越高，力控制越精确。在进行力控制任务时，通过记录中心区域的脑电图测量了运动周围的阿尔法和贝塔事件相关不同步（ERD）以及力的准确性和稳定性。结果表明，虽然力的准确性和稳定性随着视觉增益的增加而显著提高，但 WM 负荷对这些指标没有显著影响。阿尔法和贝塔ERD在高视觉增益下比低视觉增益下更大，在高WM负荷下也比低WM负荷下更大。这些研究结果表明，在青壮年中，WM 负荷的增加会导致感觉运动皮层活动的补偿性增加，从而缓解因 WM 负荷导致神经资源耗竭而可能造成的静态力控制性能下降。我们的研究结果扩展了目前对 WM 与感觉运动过程之间相互作用的理解，为了解与运动相关的大脑活动如何受到 WM 负荷增加的影响提供了新的见解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Neuropsychologia 医学-行为科学

CiteScore

5.10

自引率

3.80%

发文量

228

审稿时长

4 months

期刊介绍： Neuropsychologia is an international interdisciplinary journal devoted to experimental and theoretical contributions that advance understanding of human cognition and behavior from a neuroscience perspective. The journal will consider for publication studies that link brain function with cognitive processes, including attention and awareness, action and motor control, executive functions and cognitive control, memory, language, and emotion and social cognition.