皮肤对适应性精确抓握的作用。

The cutaneous contribution to adaptive precision grip.

作者信息

Witney Alice G, Wing Alan, Thonnard Jean-Louis, Smith Allan M

机构信息

Department of Zoology, University of Cambridge, Downing Street, Cambridge CB2 3EJ, UK.

出版信息

Trends Neurosci. 2004 Oct;27(10):637-43. doi: 10.1016/j.tins.2004.08.006.

DOI:10.1016/j.tins.2004.08.006

PMID:15374677

Abstract

Only after injury, or perhaps prolonged exposure to cold that is sufficient to numb the fingers, do we suddenly appreciate the complex neural mechanisms that underlie our effortless dexterity in manipulating objects. The nervous system is capable of adapting grip forces to a wide range of object shapes, weights and frictional properties, to provide optimal and secure handling in a variety of potentially perturbing environments. The dynamic interplay between sensory information and motor commands provides the basis for this flexibility, and recent studies supply somewhat unexpected evidence of the essential role played by cutaneous feedback in maintaining and acquiring predictive grip force control. These examples also offer new insights into the adaptive control of other voluntary movements.

摘要

只有在受伤之后，或者可能是长时间暴露在足以使手指麻木的寒冷环境中，我们才会突然意识到那些支撑我们轻松灵活操作物体的复杂神经机制。神经系统能够使握力适应各种物体形状、重量和摩擦特性，以便在各种潜在干扰环境中提供最佳和安全的操控。感觉信息与运动指令之间的动态相互作用为这种灵活性提供了基础，并且最近的研究提供了一些出人意料的证据，证明皮肤反馈在维持和获得预测性握力控制中所起的重要作用。这些例子也为其他自主运动的适应性控制提供了新的见解。

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皮肤对适应性精确抓握的作用。

The cutaneous contribution to adaptive precision grip.

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