猫后肢肌肉中抗疲劳运动单位的比例及其与轴突传导速度的关系。
Proportion of fatigue-resistant motor units in hindlimb muscles of cat and their relation to axonal conduction velocity.
作者信息
Emonet-Dénand F, Hunt C C, Petit J, Pollin B
机构信息
Laboratoire de Neurophysiologie, Collège de France, Paris.
出版信息
J Physiol. 1988 Jun;400:135-58. doi: 10.1113/jphysiol.1988.sp017115.
Abstract
- A study of motor units to hindlimb muscles of cat has been made, with as complete a sample as possible of the motor axons to an individual muscle. In single experiments as much as 95% of the motor supply to a muscle has been examined. 2. The following muscles have been studied: peroneus brevis, peroneus tertius, peroneus longus, plantaris, gastrocnemius medialis, soleus, tenuissimus and lumbricalis superficialis. 3. Units were identified as slow resistant (S), fast resistant (FR), fast fatigable (FF) and fast intermediate (FI). The proportion of various motor unit types differs from one muscle to another. There is also some variation in the proportions to a given muscle from one animal to another. With the exceptions of soleus, which is entirely slow resistant, and gastrocnemius, which has relatively fewer resistant units, most muscles contain 60% or more of resistant (S and FR) units. 4. The conduction velocity ranges of FF, FR and FI units overlapped. There was little overlap between the conduction velocity ranges of these F units and of S units. 5. In individual experiments there was a strong and significant positive correlation between the logarithm of maximal tetanic tension and axonal conduction velocity in S and in S+FR units. In terms of contractile response the total fatigue-resistant population appeared to be a continuum. The correlation coefficient between maximal tetanic tension and conduction velocity was also high in the totality of units of all types, although within the FF group there appeared to be little or no correlation. In pooled data there was much more scatter and these relations were less clear. This resulted largely from differences in the ranges of axonal conduction velocity for a given motor unit type from one animal to another. 6. There was a highly significant negative correlation between isometric twitch contraction time and axonal conduction velocity in individual experiments. This relationship could also be seen, but less clearly, in pooled data. 7. The possible bases for these relationships are discussed.
摘要
- 对猫后肢肌肉的运动单位进行了研究,尽可能完整地采集了支配单个肌肉的运动轴突样本。在单次实验中,对一块肌肉高达95%的运动神经支配进行了检测。2. 研究了以下肌肉:腓骨短肌、第三腓骨肌、腓骨长肌、跖肌、腓肠肌内侧头、比目鱼肌、最薄肌和浅蚓状肌。3. 运动单位被分为慢抗疲劳型(S)、快抗疲劳型(FR)、快易疲劳型(FF)和快中间型(FI)。不同运动单位类型的比例因肌肉而异。从一只动物到另一只动物,给定肌肉的比例也存在一些差异。除了完全是慢抗疲劳型的比目鱼肌和抗疲劳单位相对较少的腓肠肌外,大多数肌肉含有60%或更多的抗疲劳(S和FR)单位。4. FF、FR和FI单位的传导速度范围有重叠。这些F单位和S单位的传导速度范围之间几乎没有重叠。5. 在单次实验中,S型和S+FR型单位的最大强直张力对数与轴突传导速度之间存在强烈且显著的正相关。就收缩反应而言,总的抗疲劳群体似乎是一个连续体。在所有类型的单位总体中,最大强直张力与传导速度之间的相关系数也很高,尽管在FF组内似乎几乎没有相关性。在汇总数据中,离散度更大,这些关系不太明显。这主要是由于给定运动单位类型的轴突传导速度范围在不同动物之间存在差异。6. 在单次实验中,等长单收缩时间与轴突传导速度之间存在高度显著的负相关。在汇总数据中也可以看到这种关系,但不太明显。7. 讨论了这些关系可能的基础。
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