Forster R E, Crandall E D
J Appl Physiol. 1975 Apr;38(4):710-8. doi: 10.1152/jappl.1975.38.4.710.
A stopped-flow rapid-reaction apparatus was used to follow the time course of extracellular pH in a human red cell suspension following a sudden increase in PCO2. The extracellular pH change was slow (t1/2 similar to 3.5 s) considering the presence of carbonic anhydrase in the cells. When carbonic anhydrase was added to the extracellular fluid, the half-time was reduced to less than 20 ms. The explanation for these phenomena is that the equilibration of H+ across the red cell membrane is rate-limited by the uncatalyzed reaction CO2 plus H2O formed from H2CO3 outside the cells. A theoretical model was developed which successfully reproduced the experimental results. When the model was used to simulate CO2 exchange in vivo, it was determined that blood PCO2 and pH require long times (greater than 50 s) to approach equilibrium between cells and plasma after leaving an exchange capillary. We conclude that cell-plasma equilibrium may never be reached in vivo, and that in vitro measurements of these quantities may not represent their true values at the site of sampling.
使用停流快速反应装置来跟踪人红细胞悬液中PCO2突然升高后细胞外pH的时间进程。考虑到细胞中存在碳酸酐酶,细胞外pH变化缓慢(半衰期约为3.5秒)。当向细胞外液中加入碳酸酐酶时,半衰期缩短至小于20毫秒。这些现象的解释是,H+跨红细胞膜的平衡受细胞外由H2CO3形成的未催化反应CO2 + H2O的速率限制。开发了一个理论模型,该模型成功地再现了实验结果。当该模型用于模拟体内CO2交换时,确定血液PCO2和pH在离开交换毛细血管后需要很长时间(大于50秒)才能在细胞和血浆之间达到平衡。我们得出结论,体内可能永远无法达到细胞 - 血浆平衡,并且这些量的体外测量可能不代表采样部位的真实值。
