人类在腕关节伸展和手部握拳过程中,已确定类型的腕伸肌运动单位的放电模式。
Firing pattern of type-identified wrist extensor motor units during wrist extension and hand clenching in humans.
作者信息
Sturm H, Schmied A, Vedel J P, Pagni S
机构信息
Laboratoire de Physiologie et Physiopathologie Neuromusculaire Humaine, CNRS-UPR Neurobiologie et Mouvements, Marseille, France.
出版信息
J Physiol. 1997 Nov 1;504 ( Pt 3)(Pt 3):735-45. doi: 10.1111/j.1469-7793.1997.735bd.x.
Abstract
- Single motor unit activity was investigated in the extensor carpi radialis muscles during voluntary isometric contraction involving either the coactivation of the wrist agonist extensor muscles (wrist extension) or the coactivation of the wrist and finger antagonist extensor and flexor muscles (hand clenching). 2. The motor units were found to be activated at a similar level of motoneurone pool drive during both wrist extension and hand clenching, as indicated by the fact that the EMG activity at which they were recruited was practically the same in both cases (mean +/- S.D.: 20 +/- 26 and 21 +/- 25 mV, respectively). In addition, the net excitatory drive exerted on the motoneurones, as assessed from the mean interspike intervals, did not differ significantly between the two tasks (mean +/- S.D.: 104.57 +/- 17.24 and 103.01 +/- 16.26 ms, for wrist extension and hand clenching, respectively). 3. However, the discharge variability, in terms of the coefficient of variation of the interspike intervals, was slightly but significantly greater during hand clenching than during wrist extension (0.213 +/- 0.049 and 0.198 +/- 0.045, respectively). This increase involved all types of motor units, regardless of their contractile force. 4. We suggest that the greater motoneurone discharge variability observed during hand clenching may be attributable to an increase in the synaptic noise. This increase might be due to the activation of numerous afferent pathways mediating reciprocal interactions between antagonist motoneurone pools, as well as to the activation of hand cutaneous receptors that play a major role in the regulation of handling and gripping motor activities.
摘要
- 在涉及腕部伸展肌协同激活(腕部伸展)或腕部和手指拮抗肌伸展肌与屈肌协同激活(手部紧握)的随意等长收缩过程中,对桡侧腕伸肌的单运动单位活动进行了研究。2. 发现在腕部伸展和手部紧握过程中,运动单位在相似的运动神经元池驱动水平下被激活,这一事实表明,两种情况下它们被募集时的肌电图活动实际上是相同的(平均值±标准差:分别为20±26和21±25 mV)。此外,根据平均峰间期评估,施加在运动神经元上的净兴奋性驱动在两项任务之间没有显著差异(腕部伸展和手部紧握时的平均值±标准差分别为104.57±17.24和103.01±16.26 ms)。 3. 然而,就峰间期变异系数而言,手部紧握时的放电变异性略高于腕部伸展时,但差异显著(分别为0.213±0.049和0.198±0.045)。这种增加涉及所有类型的运动单位,无论其收缩力如何。4. 我们认为,在手部紧握过程中观察到的更大的运动神经元放电变异性可能归因于突触噪声的增加。这种增加可能是由于介导拮抗运动神经元池之间相互作用的众多传入通路的激活,以及在调节操作和抓握运动活动中起主要作用的手部皮肤感受器的激活。
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