青蛙肌肉两个连续等长强直收缩过程中能量平衡的比较。
A comparison of the energy balance in two successive isometric tetani of frog muscle.
作者信息
Curtin N A, Woledge R C
出版信息
J Physiol. 1977 Sep;270(2):455-71. doi: 10.1113/jphysiol.1977.sp011962.
Abstract
- Measurements were made of the energy produced as heat and work (h + w) and the chemical changes which occurred between the beginning and end of each of two periods of stimulation. The muscles contracted tetanically under isometric conditions. Each period of stimulation (tetanus) lasted 5 sec and there was an interval of 3 sec between them. The tension developed in the second tetanus was 91% of that in the first.2. The observed (h + w) was greater in each tetanus than the quantity expected from the measured chemical changes. This excess was 230 +/- 43 mJ/g dry wt. (mean +/- S.E. of mean) in the first tetanus, but only 89 +/- 46 mJ/g in the second tetanus (mean +/- S.E. of mean). The result for the first tetanus agrees with previous findings.3. The observed (h + w) was divided into two parts, labile and stable, which were defined by Aubert (1956). This division was made on the basis of the time course of the (h + w) production, without reference to the chemical changes. The labile part of the (h + w) has an exponentially declining rate, and the stable part has a constant rate.4. The observed (h + w) was less in the second tetanus than in the first. This was due largely to the decrease in the labile part in the second tetanus; it was only ca. 0.35 of that in the first tetanus. However, the stable part remained relatively constant, 0.83 of that in the first tetanus. Aubert & Maréchal (1963) and Aubert (1968) have reported similar results.5. Having divided the (h + w) into the stable and labile parts, we found that the stable part could be accounted for by the chemical change, but the labile part could not. Thus, for both tetani, the stable part of the energy is about equal to the explained energy, and the labile part is about equal to the unexplained energy. The possible interpretations of these equalities are discussed.
摘要
对在两个刺激周期开始和结束之间产生的作为热量和功(h + w)的能量以及发生的化学变化进行了测量。肌肉在等长条件下强直收缩。每个刺激周期(强直收缩)持续5秒,它们之间有3秒的间隔。第二次强直收缩中产生的张力是第一次的91%。
在每次强直收缩中观察到的(h + w)大于根据测量的化学变化预期的量。第一次强直收缩中这种过量为230±43 mJ/g干重(平均值±平均值的标准误),但第二次强直收缩中仅为89±46 mJ/g(平均值±平均值的标准误)。第一次强直收缩的结果与先前的发现一致。
观察到的(h + w)被分为不稳定和稳定两部分,这是由奥贝尔(1956年)定义的。这种划分是基于(h + w)产生的时间进程,而不参考化学变化。(h + w)的不稳定部分具有指数下降率,而稳定部分具有恒定速率。
第二次强直收缩中观察到的(h + w)比第一次少。这主要是由于第二次强直收缩中不稳定部分的减少;它仅约为第一次的0.35。然而,稳定部分保持相对恒定,为第一次的0.83。奥贝尔和马雷夏尔(1963年)以及奥贝尔(1968年)报告了类似的结果。
将(h + w)分为稳定和不稳定部分后,我们发现稳定部分可以由化学变化来解释,但不稳定部分不能。因此,对于两次强直收缩,能量的稳定部分大约等于可解释的能量,而不稳定部分大约等于无法解释的能量。讨论了这些等式的可能解释。
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