运动原基——新数据与未来问题

Motor primitives--new data and future questions.

作者信息

Giszter Simon F

机构信息

Neurobiology and Anatomy, Drexel University College of Medicine, Philadelphia, PA, 19129 USA.

出版信息

Curr Opin Neurobiol. 2015 Aug;33:156-65. doi: 10.1016/j.conb.2015.04.004. Epub 2015 Apr 22.

DOI:10.1016/j.conb.2015.04.004

PMID:25912883

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6524953/

Abstract

Motor primitives allow integration across scales in the motor system and may link movement construction and circuit organization. This review examines support for primitives, and new data relating primitives to concrete circuit elements across species. Both kinematic motor primitives and muscle synergy/kinetic motor primitives are reviewed. Motor primitives allow a modular hierarchy that may be re-used by volitional systems in novel ways. They can provide a developmental bootstrap for ethologically important actions. Collections of primitives somewhat constrain motor acts, but at the same time sets of primitives facilitate the rapid construction of these constrained actions, and can allow use of simpler controls. Novel motor skill likely requires augmentation to transcend the constraints present in initial collections of low level motor primitives. The benefits and limitations of motor primitives and the recognized knowledge gaps and needs for future research are briefly discussed.

摘要

运动基元允许运动系统在不同尺度上进行整合，并可能将运动构建与神经回路组织联系起来。本综述探讨了对运动基元的支持，以及跨物种将运动基元与具体神经回路元件相关联的新数据。对运动学运动基元以及肌肉协同作用/动力学运动基元都进行了综述。运动基元允许一种模块化层次结构，意志系统可以以新颖的方式重新利用这种结构。它们可以为具有行为学重要性的动作提供发育上的引导。运动基元的集合在一定程度上限制了运动行为，但同时运动基元集也有助于快速构建这些受限动作，并可以允许使用更简单的控制方式。新的运动技能可能需要增强，以超越低水平运动基元初始集合中存在的限制。本文简要讨论了运动基元的益处和局限性，以及公认的知识空白和未来研究的需求。

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