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Literature DB >> 5642471

Further observations on asymmetrical solute movement across membranes.

Abstract

The permeability of frog skin under the influence of urea hyperosmolarity has been studied. Flux ratio asymmetry has been demonstrated again for tracer mannitol. The inhibitors DNP, CN(-), and ouabain have been used to eliminate active sodium transport and it was found that urea hyperosmolarity produces asymmetrical mannitol fluxes on frog skins having no short-circuit current. These findings suggest that flux ratio asymmetry is due to solute interaction and is unrelated to sodium transport. Studies with a synthetic membrane show clearly that bulk flow of fluid can produce a "solvent drag" effect and change flux ratios. When bulk flow is blocked and solute gradients allowed their full expression, then solute interaction "solute drag" is easily demonstrable in a synthetic system.

Entities: Chemical

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Year: 1968 PMID： 5642471 PMCID： PMC2201158 DOI： 10.1085/jgp.51.1.1

Source DB: PubMed Journal: J Gen Physiol ISSN： 0022-1295 Impact factor: 4.086

5 in total

1. Solvent drag on non-electrolytes during osmotic flow through isolated toad skin and its response to antidiuretic hormone.

Authors: B ANDERSEN; H H USSING
Journal: Acta Physiol Scand Date: 1957-06-08

2. A possible mechanism of action of DMSO.

Authors: T J Franz; J T Van Bruggen
Journal: Ann N Y Acad Sci Date: 1967-03-15 Impact factor: 5.691

3. Anomalous transport of electrolytes and sucrose through the isolated frog skin induced by hypertonicity of the outside bathing solution.

Authors: H H Ussing
Journal: Ann N Y Acad Sci Date: 1966-07-14 Impact factor: 5.691

4. Hyperosmolarity and the net transport of nonelectrolytes in frog skin.

Authors: T J Franz; J T Van Bruggen
Journal: J Gen Physiol Date: 1967-03 Impact factor: 4.086

5. Amino acid and sugar transport in rabbit ileum.

Authors: S G Schultz; R E Fuisz; P F Curran
Journal: J Gen Physiol Date: 1966-05 Impact factor: 4.086

5 in total

15 in total

1. Luminal hyperosmolarity decreases Na transport and impairs barrier function of sheep rumen epithelium.

Authors: Monika Schweigel; Markus Freyer; Sabine Leclercq; Benjamin Etschmann; Ulrike Lodemann; Almut Böttcher; Holger Martens
Journal: J Comp Physiol B Date: 2005-11-11 Impact factor: 2.200

2. Influence of membrane heterogeneity on kinetics of nonelectrolyte tracer flows.

Authors: J H Li; A Essig
Journal: J Membr Biol Date: 1976-11-22 Impact factor: 1.843

3. Solute flux coupling in a homopore membrane.

Authors: J T Van Bruggen; J D Boyett; A L van Bueren; W R Galey
Journal: J Gen Physiol Date: 1974-06 Impact factor: 4.086

4. Solvent drag by solute-linked water flow. A theoretical examination.

Authors: S Stender; K Kristensen; E Skadhauge
Journal: J Membr Biol Date: 1973 Impact factor: 1.843

5. Theoretical analysis of net tracer flux due to volume circulation in a membrane with pores of different sizes. Relation to solute drag model.

Authors: C S Patlak; S I Rapoport
Journal: J Gen Physiol Date: 1971-02 Impact factor: 4.086

6. Effects of solvent and solute drag on transmembrane diffusion.

Authors: J T Van Bruggen; B Chalmers; M Muller
Journal: J Gen Physiol Date: 1982-03 Impact factor: 4.086

7. Pathways for movement of ions and water across toad urinary bladder. I. Anatomic site of transepithelial shunt pathways.

Authors: D R DiBona; M M Civan
Journal: J Membr Biol Date: 1973 Impact factor: 1.843