Human motor learning dynamics in high-dimensional tasks.

IF 3.8 2区生物学 Q1 BIOCHEMICAL RESEARCH METHODS PLoS Computational Biology Pub Date : 2024-10-14 eCollection Date: 2024-10-01 DOI:10.1371/journal.pcbi.1012455

Ankur Kamboj, Rajiv Ranganathan, Xiaobo Tan, Vaibhav Srivastava

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Abstract

Conventional approaches to enhance movement coordination, such as providing instructions and visual feedback, are often inadequate in complex motor tasks with multiple degrees of freedom (DoFs). To effectively address coordination deficits in such complex motor systems, it becomes imperative to develop interventions grounded in a model of human motor learning; however, modeling such learning processes is challenging due to the large DoFs. In this paper, we present a computational motor learning model that leverages the concept of motor synergies to extract low-dimensional learning representations in the high-dimensional motor space and the internal model theory of motor control to capture both fast and slow motor learning processes. We establish the model's convergence properties and validate it using data from a target capture game played by human participants. We study the influence of model parameters on several motor learning trade-offs such as speed-accuracy, exploration-exploitation, satisficing, and flexibility-performance, and show that the human motor learning system tunes these parameters to optimize learning and various output performance metrics.

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高维任务中的人类运动学习动力学

在具有多个自由度（DoFs）的复杂运动任务中，提供指令和视觉反馈等增强运动协调性的传统方法往往是不够的。为了有效解决此类复杂运动系统中的协调缺陷，当务之急是以人类运动学习模型为基础开发干预措施；然而，由于多自由度较大，为此类学习过程建模极具挑战性。在本文中，我们提出了一种计算运动学习模型，该模型利用运动协同概念在高维运动空间中提取低维学习表征，并利用运动控制内部模型理论捕捉快速和慢速运动学习过程。我们建立了该模型的收敛特性，并使用人类参与者进行的目标捕捉游戏数据对其进行了验证。我们研究了模型参数对几种运动学习权衡的影响，如速度-准确性、探索-开发、满足和灵活性-性能，并表明人类运动学习系统会调整这些参数，以优化学习和各种输出性能指标。

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来源期刊

PLoS Computational Biology BIOCHEMICAL RESEARCH METHODS-MATHEMATICAL & COMPUTATIONAL BIOLOGY

CiteScore

7.10

自引率

4.70%

发文量

820

审稿时长

2.5 months

期刊介绍： PLOS Computational Biology features works of exceptional significance that further our understanding of living systems at all scales—from molecules and cells, to patient populations and ecosystems—through the application of computational methods. Readers include life and computational scientists, who can take the important findings presented here to the next level of discovery. Research articles must be declared as belonging to a relevant section. More information about the sections can be found in the submission guidelines. Research articles should model aspects of biological systems, demonstrate both methodological and scientific novelty, and provide profound new biological insights. Generally, reliability and significance of biological discovery through computation should be validated and enriched by experimental studies. Inclusion of experimental validation is not required for publication, but should be referenced where possible. Inclusion of experimental validation of a modest biological discovery through computation does not render a manuscript suitable for PLOS Computational Biology. Research articles specifically designated as Methods papers should describe outstanding methods of exceptional importance that have been shown, or have the promise to provide new biological insights. The method must already be widely adopted, or have the promise of wide adoption by a broad community of users. Enhancements to existing published methods will only be considered if those enhancements bring exceptional new capabilities.