A Dynamical Approach to the Uncontrolled Manifold: Predicting Performance Error During Steady-State Isometric Force Production.

IF 0.9 4区医学 Q4 NEUROSCIENCES

Motor Control Pub Date : 2022-07-23 Print Date: 2022-10-01 DOI:10.1123/mc.2021-0105

Francis M Grover, Valéria Andrade, Nicole S Carver, Scott Bonnette, Michael A Riley, Paula L Silva

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引用次数: 0

Abstract

The uncontrolled manifold (UCM) approach quantifies the presence of compensatory variability between musculoskeletal elements involved in a motor task. This approach has proved useful for identifying synergistic control strategies for a variety of everyday motor tasks and for investigating how control strategies are affected by motor pathology. However, the UCM approach is limited in its ability to relate compensatory motor variance directly to task performance because variability along the UCM is mathematically agnostic to performance. We present a new approach to UCM analysis that quantifies patterns of irregularity in the compensatory variability between motor elements over time. In a bimanual isometric force stabilization task, irregular patterns of compensation between index fingers predicted greater performance error associated with difficult task conditions, in particular for individuals who exploited a larger set of compensatory strategies (i.e., a larger subspace of the UCM). This relationship between the amount and structure of compensatory motor variance might be an expression of underlying processes supporting performance resilience.

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非控制流形的动力学方法:预测稳态等距力产生过程中的性能误差。

不受控制的歧管(UCM)方法量化了参与运动任务的肌肉骨骼元素之间代偿变异性的存在。这种方法已被证明对确定各种日常运动任务的协同控制策略和研究控制策略如何受到运动病理的影响是有用的。然而，UCM方法在将代偿性运动方差直接与任务绩效联系起来的能力上是有限的，因为沿着UCM的可变性在数学上与绩效无关。我们提出了一种新的UCM分析方法，量化了运动元素之间代偿变异性的不规则模式。在双手等距力稳定任务中，食指之间不规则的补偿模式预示着与困难任务条件相关的更大的表现误差，特别是对于那些利用更大的补偿策略集(即更大的UCM子空间)的个体。代偿性运动变异的数量和结构之间的这种关系可能是支持表现弹性的潜在过程的表达。

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

Motor Control 医学-神经科学

CiteScore

1.80

自引率

9.10%

发文量

审稿时长

>12 weeks

期刊介绍： Motor Control (MC), a peer-reviewed journal, provides a multidisciplinary examination of human movement across the lifespan. To keep you abreast of current developments in the field of motor control, it offers timely coverage of important topics, including issues related to motor disorders. This international journal publishes many types of research papers, from clinical experimental to modeling and theoretical studies. These papers come from such varied disciplines as biomechanics, kinesiology, neurophysiology, neuroscience, psychology, physical medicine, and rehabilitation. Motor Control, the official journal of the International Society of Motor Control, is designed to provide a multidisciplinary forum for the exchange of scientific information on the control of human movement across the lifespan, including issues related to motor disorders. Motor Control encourages submission of papers from a variety of disciplines including, but not limited to, biomechanics, kinesiology, neurophysiology, neuroscience, psychology, physical medicine, and rehabilitation. This peer-reviewed journal publishes a wide variety of types of research papers including clinical experimental, modeling, and theoretical studies. To be considered for publication, papers should clearly demonstrate a contribution to the understanding of control of movement. In addition to publishing research papers, Motor Control publishes review articles, quick communications, commentaries, target articles, and book reviews. When warranted, an entire issue may be devoted to a specific topic within the area of motor control.