Takeguchi N, Nakagaki M
Biophys J. 1969 Aug;9(8):1029-44. doi: 10.1016/s0006-3495(69)86434-9.
Theoretical and experimental studies have been made on permeability coefficients to various kinds of electrolyte across lens capsules that are dissected from bovine eyes and that are found to be positively fixed charged membranes from our experiments of membrane potentials. The differential permeability coefficient, P(m), is defined as J(s) = P(m)(C(2) - C(1)), where J(s) is the flux of an electrolyte component in moles per sec across unit area of the lens capsule that separates two aqueous solutions of the same electrolyte at different concentrations, C(2) and C(1). Various types of strong electrolytes were studied; KCl, NaCl, Cacl(2), MgSO(4), MgCl(2) and LaCl(3). It was found that at C(2)/C(1) = constant, P(m) decreases to zero as C(2) decreases and P(m) increases to a limiting value, (P(m))(infinity), that is characteristic for the system of the salt used and the membrane as C(2) increases, despite of electrolytes. We assumed in theory that single ion activity coefficients of co-ion and gegen-ion are ideal, that the systems studied are in electric neutrality, that the fixed charge density of the membrane is independent of concentrations C(2), and that Donnan equilibrium holds between the bulk solution and membrane surface. Although the concentration-dependent changes of P(m) were quantitatively different depending on the type of electrolyte used, general agreement between theory and experiment was obtained over a wide range of concentrations except for the case of very dilute solutions.
针对从牛眼中分离出的晶状体囊对各种电解质的渗透系数进行了理论和实验研究。通过膜电位实验发现,晶状体囊是带正电的固定电荷膜。微分渗透系数P(m)定义为J(s)=P(m)(C(2)-C(1)),其中J(s)是电解质组分以摩尔每秒为单位穿过分隔两种不同浓度相同电解质水溶液的晶状体囊单位面积的通量,C(2)和C(1)分别为两种浓度。研究了各种类型的强电解质,包括KCl、NaCl、CaCl(2)、MgSO(4)、MgCl(2)和LaCl(3)。结果发现,当C(2)/C(1)为常数时,随着C(2)降低,P(m)降至零;随着C(2)升高,P(m)增加至一个极限值(P(m))(infinity),该极限值对于所使用的盐和膜的系统而言是特征性的,与电解质种类无关。我们在理论上假定,同离子和反离子的单离子活度系数是理想的,所研究的系统呈电中性,膜的固定电荷密度与浓度C(2)无关,且本体溶液与膜表面之间存在唐南平衡。尽管P(m)随浓度的变化在定量上因所用电解质类型而异,但除了极稀溶液的情况外,在很宽的浓度范围内理论与实验普遍相符。