Department of Exercise and Sport Sciences, University of Copenhagen, Denmark.
Acta Physiol (Oxf). 2010 Jul 1;199(3):317-26. doi: 10.1111/j.1748-1716.2010.02098.x. Epub 2010 Feb 6.
Changes in sensory information from active muscles accompany fatiguing exercise and the force-generating capacity deteriorates. The central motor commands therefore must adjust depending on the task performed. Muscle potentials evoked by transcranial magnetic stimulation (TMS) change during the course of fatiguing muscle activity, which demonstrates activity changes in cortical or spinal networks during fatiguing exercise. Here, we investigate cortical mechanisms that are actively involved in driving the contracting muscles.
During a sustained submaximal contraction (30% of maximal voluntary contraction) of the elbow flexor muscles we applied TMS over the motor cortex. At an intensity below motor threshold, TMS reduced the ongoing muscle activity in biceps brachii. This reduction appears as a suppression at short latency of the stimulus-triggered average of rectified electromyographic (EMG) activity. The magnitude of the suppression was evaluated relative to the mean EMG activity during the 50 ms prior to the cortical stimulus.
During the first 2 min of the fatiguing muscle contraction the suppression was 10 +/- 0.9% of the ongoing EMG activity. At 2 min prior to task failure the suppression had reached 16 +/- 2.1%. In control experiments without fatigue we did not find a similar increase in suppression with increasing levels of ongoing EMG activity.
Using a form of TMS which reduces cortical output to motor neurones (and disfacilitates them), this study suggests that neuromuscular fatigue increases this disfacilitatory effect. This finding is consistent with an increase in the excitability of inhibitory circuits controlling corticospinal output.
主动肌肉的感觉信息在疲劳运动时会发生变化,并且产生力的能力会恶化。因此,中央运动指令必须根据所执行的任务进行调整。经颅磁刺激(TMS)诱发的肌肉电位在疲劳性肌肉活动过程中发生变化,这表明在疲劳运动期间皮质或脊髓网络中的活动发生变化。在这里,我们研究了主动参与驱动收缩肌肉的皮质机制。
在肘部屈肌的持续亚最大收缩(最大自主收缩的 30%)期间,我们在运动皮层上施加 TMS。在低于运动阈值的强度下,TMS 减少了肱二头肌的持续肌肉活动。这种减少表现为刺激触发平均整流肌电图(EMG)活动的短潜伏期抑制。抑制的幅度相对于皮质刺激前 50 毫秒内的平均 EMG 活动进行评估。
在疲劳性肌肉收缩的前 2 分钟内,抑制作用为 10 +/- 0.9%的持续 EMG 活动。在任务失败前 2 分钟,抑制作用已达到 16 +/- 2.1%。在没有疲劳的对照实验中,我们没有发现随着持续 EMG 活动水平的增加而出现类似的抑制增加。
使用一种降低运动神经元皮质输出(并使其失活)的 TMS 形式,本研究表明神经肌肉疲劳会增加这种失活效应。这一发现与控制皮质脊髓输出的抑制性回路兴奋性增加一致。
