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. 1970 Apr 1;55(4):427–450. doi: 10.1085/jgp.55.4.427

Determination of Urea Permeability in Red Cells by Minimum Method

A test of the phenomenological equations

R I Sha'afi 1,2, G T Rich 1,2, D C Mikulecky 1,2, A K Solomon 1,2
PMCID: PMC2203011  PMID: 5435779

Abstract

A new method has been developed for measuring the permeability coefficient, ω, of small nonelectrolytes. The method depends upon a mathematical analysis of the time course of cell volume changes in the neighborhood of the minimum volume following addition of a permeating solute to an isosmolal buffer. Coefficients determined by the minimum volume method agree with those obtained using radioactive tracers. ω for urea in human red cells was found to decrease as the volume flow, Jv, into the cell increased. Such behavior is entirely unexpected for a single uniform rate-limiting barrier on the basis of the linear phenomenological equations derived from irreversible thermodynamics. However, the present findings are consonant with a complex membrane system consisting of a tight barrier on the outer face of the human red cell membrane and a somewhat less restrictive barrier behind it closer to the inner membrane face. A theoretical analysis of such a series model has been made which makes predictions consistent with the experimental findings.

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Selected References

These references are in PubMed. This may not be the complete list of references from this article.

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