Raftos J E, Bulliman B T, Kuchel P W
Department of Biochemistry, University of Sydney, New South Wales, Australia.
J Gen Physiol. 1990 Jun;95(6):1183-204. doi: 10.1085/jgp.95.6.1183.
When erythrocytes are suspended in a solution of known composition the resultant values of such basic cell parameters as volume and pH are difficult to predict. To facilitate such predictions, we developed a mathematical model describing the passive transmembrane distribution of permeant species; three simultaneous equations were produced. Certain essential data required for the model were determined experimentally; these included the pH dependence of the charge on the hemoglobin molecule and the variation of the osmotic coefficient of hemoglobin with cell volume. Finally, cells were added to various solutions, and then titrated to produce a wide pH range (pH 6-8). We measured the resultant cell volume, cellular and extracellular pH using both conventional and 31P NMR methods. The expected equilibrium values of these electrochemical parameters were also calculated by solving (numerically) the three model equations. The accuracy of the model simulations was evaluated by direct comparison of calculated and experimentally determined values.
当红细胞悬浮于已知成分的溶液中时,诸如体积和pH等基本细胞参数的最终值很难预测。为便于进行此类预测,我们开发了一个描述渗透物质被动跨膜分布的数学模型;由此得出了三个联立方程。该模型所需的某些关键数据通过实验确定;其中包括血红蛋白分子电荷的pH依赖性以及血红蛋白渗透系数随细胞体积的变化。最后,将细胞加入各种溶液中,然后进行滴定以产生较宽的pH范围(pH 6 - 8)。我们使用传统方法和³¹P NMR方法测量了由此产生的细胞体积、细胞内和细胞外pH。这些电化学参数的预期平衡值也通过(数值)求解三个模型方程来计算。通过直接比较计算值和实验测定值来评估模型模拟的准确性。