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与人类运动神经元的平台样行为一致的大的非随意力。

Large involuntary forces consistent with plateau-like behavior of human motoneurons.

作者信息

Collins D F, Burke D, Gandevia S C

机构信息

Spinal Injury Research Centre, Prince of Wales Medical Research Institute and University of New South Wales, Randwick, Sydney, Australia 2031.

出版信息

J Neurosci. 2001 Jun 1;21(11):4059-65. doi: 10.1523/JNEUROSCI.21-11-04059.2001.

DOI:10.1523/JNEUROSCI.21-11-04059.2001
PMID:11356893
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6762712/
Abstract

When electrical stimulation is applied over human muscle, the evoked force is generally considered to be of peripheral origin. However, in relaxed humans, stimulation (1 msec pulses, 100 Hz) over the muscles that plantarflex the ankle produced more than five times more force than could be accounted for by peripheral properties. This additional force was superimposed on the direct response to motor axon stimulation, produced up to 40% of the force generated during a maximal voluntary contraction, and was abolished during anesthesia of the tibial nerve proximal to the stimulation site. It therefore must have resulted from the activation of motoneurons within the spinal cord. The additional force could be initiated by stimulation of low-threshold afferents, distorted the classical relationship between force and stimulus frequency, and often outlasted the stimulation. The mean firing rate of 27 soleus motor units recorded during the sustained involuntary activity after the stimulation was 5.8 +/- 0.2 Hz. The additional force increments were not attributable to voluntary intervention because they were present in three sleeping subjects and in two subjects with lesions of the thoracic spinal cord. The phenomenon is consistent with activation of plateau potentials within motoneurons and, if so, the present findings imply that plateau potentials can make a large contribution to forces produced by the human nervous system.

摘要

当对人体肌肉施加电刺激时,诱发的力量通常被认为源于外周。然而,在放松的人体中,对使踝关节跖屈的肌肉进行刺激(1毫秒脉冲,100赫兹)所产生的力量比外周特性所能解释的力量多出五倍以上。这种额外的力量叠加在对运动轴突刺激的直接反应上,产生的力量高达最大自主收缩时所产生力量的40%,并且在刺激部位近端的胫神经麻醉期间消失。因此,它一定是由脊髓内运动神经元的激活引起的。这种额外的力量可以由低阈值传入神经的刺激引发,扭曲了力量与刺激频率之间的经典关系,并且常常在刺激结束后持续存在。在刺激后持续的非自主活动期间记录的27个比目鱼肌运动单位的平均放电频率为5.8±0.2赫兹。额外的力量增加并非归因于自主干预,因为在三名睡眠受试者和两名胸段脊髓损伤的受试者中也存在这种情况。这种现象与运动神经元内平台电位的激活一致,如果是这样,目前的研究结果意味着平台电位对人类神经系统产生的力量有很大贡献。

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