在持续最大自主收缩中无神经肌肉传递失败。
The absence of neuromuscular transmission failure in sustained maximal voluntary contractions.
作者信息
Bigland-Ritchie B, Kukulka C G, Lippold O C, Woods J J
出版信息
J Physiol. 1982 Sep;330:265-78. doi: 10.1113/jphysiol.1982.sp014340.
Abstract
- Muscle mass action potentials (M waves) were evoked by supramaximal single shocks to the ulnar nerve given at 5-10 s intervals throughout sustained isometric maximal voluntary contractions (m.v.c.) of the adductor pollicis and first dorsal interosseous muscles. Both muscles were fatigued simultaneously. Recordings were made from the muscle surface and also intramuscularly. 2. During a maximal contraction lasting for 60 s there was 30-50% loss of force. No decline was observed in intramuscularly recorded M wave amplitude, while the areas of the total and half M wave forms increased due to a slowing in conduction velocity. The area measured over a fixed time period declined. No evidence was obtained that these M wave potentials were contaminated by electrical activity arising in adjacent muscles. The size of the single unit potentials appeared to remain unaltered during maximal voluntary activity. 3. We conclude that neuromuscular block is not a cause of force loss during this type of fatiguing voluntary contraction.
摘要
- 在拇收肌和第一背侧骨间肌持续等长最大自主收缩(m.v.c.)过程中,每隔5 - 10秒对尺神经进行一次超强单刺激,诱发肌肉动作电位(M波)。两块肌肉同时疲劳。记录来自肌肉表面以及肌肉内部。2. 在持续60秒的最大收缩过程中,力量损失30 - 50%。肌肉内记录的M波振幅未观察到下降,而由于传导速度减慢,总M波和半M波的面积增加。在固定时间段内测量的面积下降。没有证据表明这些M波电位被相邻肌肉产生的电活动所污染。在最大自主活动期间,单个单位电位的大小似乎保持不变。3. 我们得出结论,在这种类型的疲劳性自主收缩过程中,神经肌肉阻滞不是力量损失的原因。
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