犬肋间外肌和肋间内肌活动的空间分布
Spatial distribution of external and internal intercostal activity in dogs.
作者信息
Legrand A, De Troyer A
机构信息
Laboratory of Cardiorespiratory Physiology, Brussels School of Medicine, and Chest Service, Erasme University Hospital, 1070 Brussels, Belgium.
出版信息
J Physiol. 1999 Jul 1;518(Pt 1):291-300. doi: 10.1111/j.1469-7793.1999.0291r.x.
Abstract
- The observation that the external and internal interosseous intercostal muscles in the dog show marked regional differences in mechanical advantage has prompted us to re-examine the topographic distribution of electrical activity among these muscles during spontaneous breathing. 2. Inspiratory activity was recorded only from the areas of the external intercostals with an inspiratory mechanical advantage, and expiratory activity was recorded only from the areas of the internal intercostals with an expiratory mechanical advantage. The expiratory discharges previously recorded from the caudal external intercostals and the inspiratory discharges recorded from the rostral internal intercostals were probably due to cross-contamination. 3. Activity in each muscle area was also quantified relative to the activity measured during tetanic, supramaximal nerve stimulation (maximal activity). External intercostal inspiratory activity was consistently greater in the areas with a greater inspiratory advantage (i.e. the dorsal aspect of the rostral segments) than in the areas with a smaller inspiratory advantage, and internal intercostal expiratory activity was invariably greatest in the areas with the greatest expiratory advantage (i.e. the dorsal aspect of the caudal segments). 4. This topographic distribution of neural drive confers to the external intercostal muscles an inspiratory action on the lung during breathing and to the internal interosseous intercostals an expiratory action.
摘要
- 观察发现,犬的肋间外肌和肋间内肌在机械优势方面存在显著的区域差异,这促使我们重新审视这些肌肉在自主呼吸过程中电活动的地形分布。2. 吸气活动仅在具有吸气机械优势的肋间外肌区域记录到,呼气活动仅在具有呼气机械优势的肋间内肌区域记录到。先前从尾侧肋间外肌记录到的呼气放电以及从吻侧肋间内肌记录到的吸气放电可能是由于交叉污染所致。3. 还相对于强直、超强神经刺激期间测量的活动(最大活动)对每个肌肉区域的活动进行了量化。在具有较大吸气优势的区域(即吻侧节段的背侧),肋间外肌的吸气活动始终大于在具有较小吸气优势的区域,而肋间内肌的呼气活动在具有最大呼气优势的区域(即尾侧节段的背侧)总是最大的。4. 这种神经驱动的地形分布赋予肋间外肌在呼吸过程中对肺的吸气作用,赋予肋间内肌呼气作用。
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