Determination of Equivalent Pore Radius for Human Red Cells by Osmotic Pressure Measurement

doi:10.1085/jgp.44.1.1

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Determination of Equivalent Pore Radius for Human Red Cells by Osmotic Pressure Measurement

David A. Goldstein ¹ and A. K. Solomon ¹

¹ From the Biophysical Laboratory, Harvard Medical School, Boston

A new method has been developed to measure the equivalent poreradius in cellular membranes, and has been applied to humanred cells. When red cells are suddenly introduced into a non-isosmolarconcentration of non-lipid-soluble non-electrolyte molecules,water will enter or leave the cell. The rate of cell swellingor shrinking is determined and extrapolated to zero time togive the initial rate of volume change. By suitable adjustmentof the concentration of the external solution the initial ratemay be brought to zero. The transient equilibrium concentration,determined by interpolation from experimental data, gives ameasure of Staverman's reflection coefficient, $sigma$ . The zero timemethod has enabled us to determine $sigma$ for nine permeant molecules. $sigma$ is directly related to the equivalent pore radius; the experimentaldata lead to a value of 4.2 Å for the equivalent poreradius in man, in good agreement with the previous figure of3.5 Å given by Paganelli and Solomon. The zero time methodoffers a number of advantages over previous methods for determinationof this parameter. It requires no measurement of the rate ofwater entrance into the cell, and is essentially independentof the kinetics of cell swelling. It may be applied to a varietyof living cells so that many additional membranes may now becharacterized in terms of their equivalent pore radius.

Submitted on February 26, 1960

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