犬腓肠肌工作时的组织间液pH值。

The interstitial pH of the working gastrocnemius muscle of the dog.

作者信息

Steinhagen C, Hirche H J, Nestle H W, Bovenkamp U, Hosselmann I

出版信息

Pflugers Arch. 1976 Dec 28;367(2):151-6. doi: 10.1007/BF00585151.

Abstract

In isolated gastrocnemius muscles from 19 dogs the interstitial H+ activity ([H+]int) was measured with bulb-type buffer-filled glass minielectrodes. The muscles were working isotonically and perfused with blood. In addition arterial and venous pH, venous O2 saturation, muscle temperature, and blood flow were meausred continuously at rest, during 12 min of sustained exercise, and in the recovery period. Lactate (LA-) release and O2 consumption were calculated by the Fick principle. The experiments were performed under normal acid-base conditions and during artificially induced metabolic acidosis and alkalosis. 1. In normal acid-base balance [H+]int at rest was 54 +/- 3.3 neq/l (= pH 7.24), while venous H+ ([H+]ven) was 45 +/- 4.7 neq/l (= pH 7.34) A[H+] gradient was always observed between interstitial fluid and venous blood. 2. Immediately after onset of exercise [H+]int decreased transiently. After about 15 s [H+]int increased rapidly up to values of 105 +/- 7 neq/l (= pH 6.98). In the recovery period [H+]int diminished and reached control values after about 20-30 min. [H+]ven increased up to 74.4 +/- 8.4 neq/l (= pH 7.13). Maximal gradients between [H+]int and [H+]ven were 36 neq/l (= pH 0.2). 3. During repeated exercise the decrease in [H+]int at the onset of exercise was more extensive, while the subsequent increase was lowered. These changes correspond to a smaller LA- release. 4. During metabolic alkalosis at the onset of exercise [h+]int decreased less, during metabolic acidosis more than under normal acid-base conditions. Thereafter during metabolic alkalosis maximal values of 95.4 +/ 2 neq/l (= pH 7.03), during metabolic acidosis of 180 +/- 8.6 neq/l (= pH 6.74) were reached. This led to [H+] gradients between interstitial fluid and venous blood which were much higher in metabolic acidosis than in normal acid-base balance or in metabolic alkalosis. In metabolic acidosis [H+]int decreased very sle rapidly than during metabolic alkalosis or during normal acid-base conditions. It is concluded that the H+ activity measured is that within the interstitial space. Exercise hyperemia is not caused by changes of [H+]int. Mechanisms are discussed which may explain H+ gradients between interstitial fluid and venous blood and rapid changes of [H+]int at the onset of exercise.

摘要

在19只狗的离体腓肠肌中，用球型缓冲液填充的玻璃微电极测量了组织间隙H⁺活性（[H⁺]int）。肌肉进行等张收缩并灌注血液。此外，在静息状态、持续运动12分钟期间及恢复期间，连续测量动脉和静脉pH值、静脉血氧饱和度、肌肉温度和血流量。根据菲克原理计算乳酸（LA⁻）释放量和耗氧量。实验在正常酸碱条件下以及人工诱导的代谢性酸中毒和碱中毒期间进行。1. 在正常酸碱平衡时，静息状态下的[H⁺]int为54±3.3纳摩尔/升（=pH 7.24），而静脉H⁺（[H⁺]ven）为45±4.7纳摩尔/升（=pH 7.34）。在组织间隙液和静脉血之间始终观察到Δ[H⁺]梯度。2. 运动开始后，[H⁺]int立即短暂下降。约15秒后，[H⁺]int迅速上升至105±7纳摩尔/升（=pH 6.98）。在恢复期间，[H⁺]int降低，约20 - 30分钟后达到对照值。[H⁺]ven上升至74.4±8.4纳摩尔/升（=pH 7.13）。[H⁺]int和[H⁺]ven之间的最大梯度为36纳摩尔/升（=pH 0.2）。3. 在重复运动期间，运动开始时[H⁺]int的下降更为明显，而随后的上升则降低。这些变化对应于较小的LA⁻释放量。4. 在代谢性碱中毒时，运动开始时[H⁺]int下降较少，在代谢性酸中毒时比正常酸碱条件下下降更多。此后，在代谢性碱中毒时达到最大值95.4±2纳摩尔/升（=pH 7.03），在代谢性酸中毒时达到180±8.6纳摩尔/升（=pH 6.74）。这导致组织间隙液和静脉血之间的[H⁺]梯度在代谢性酸中毒时比正常酸碱平衡或代谢性碱中毒时高得多。在代谢性酸中毒时，[H⁺]int下降速度比代谢性碱中毒或正常酸碱条件下快得多。结论是所测量的H⁺活性是组织间隙内的活性。运动性充血不是由[H⁺]int的变化引起的。讨论了解释组织间隙液和静脉血之间H⁺梯度以及运动开始时[H⁺]int快速变化的机制。

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犬腓肠肌工作时的组织间液pH值。

The interstitial pH of the working gastrocnemius muscle of the dog.

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