The unidirectional flux of an ionic species may occur because of several mechanisms such as active transport, passive diffusion, exchange diffusion, etc. The contribution of such mechanisms to the total unidirectional flux across a membrane cannot be determined by only measuring that flux. It is shown that if the pertinent experimental data (the opposite unidirectional fluxes and the composite phenomenological resistance coefficient of the ionic species for a given electrochemical potential difference) obey a certain inequality, then the parameters of a model consisting of parallel, independent, active transport, and passive processes may be determined. Although the existence of “additional” processes including exchange diffusion, single-fi...
The major part of this thesis is concerned with the study of transport and diffusion processes in io...
Derivations of the Ussing flux ratio equation have, until now, required the membrane to be both boun...
Ion flux through membrane channels is passively driven by the electrochemical potential differences ...
The unidirectional flux of an ionic species may occur because of several mechanisms such as active t...
The electrodiffusion model presented in the previous paper, which specifically excludes ion-ion inte...
Active sodium transport across epithelial membranes has been analyzed by means of linear nonequilibi...
Ions crossing biological membranes are described as a concentration of charge flowing through a sele...
A method is presented by which the steady-state properties of an homogeneous, permselective membrane...
A study of the transport properties of normal and expanded forms of a cation exchange membrane in 0....
The usual assumption in treating the diffusion of ions in an electric field has been that the moveme...
The formalisms of irreversible thermodynamics are used to describe multi-ionic nonconvective flow th...
A kinetic analysis of membrane conductance under conditions of stationary flow is presented. The sem...
In this note, we analyze ionic transport in lipid model bilayers across pre-existing transmembrane w...
Discussions of active transport usually assume stoichiometry between the rate of transport J+ and th...
In order to analyze the energetics of active transport, a hypothetical carrier model is considered i...
The major part of this thesis is concerned with the study of transport and diffusion processes in io...
Derivations of the Ussing flux ratio equation have, until now, required the membrane to be both boun...
Ion flux through membrane channels is passively driven by the electrochemical potential differences ...
The unidirectional flux of an ionic species may occur because of several mechanisms such as active t...
The electrodiffusion model presented in the previous paper, which specifically excludes ion-ion inte...
Active sodium transport across epithelial membranes has been analyzed by means of linear nonequilibi...
Ions crossing biological membranes are described as a concentration of charge flowing through a sele...
A method is presented by which the steady-state properties of an homogeneous, permselective membrane...
A study of the transport properties of normal and expanded forms of a cation exchange membrane in 0....
The usual assumption in treating the diffusion of ions in an electric field has been that the moveme...
The formalisms of irreversible thermodynamics are used to describe multi-ionic nonconvective flow th...
A kinetic analysis of membrane conductance under conditions of stationary flow is presented. The sem...
In this note, we analyze ionic transport in lipid model bilayers across pre-existing transmembrane w...
Discussions of active transport usually assume stoichiometry between the rate of transport J+ and th...
In order to analyze the energetics of active transport, a hypothetical carrier model is considered i...
The major part of this thesis is concerned with the study of transport and diffusion processes in io...
Derivations of the Ussing flux ratio equation have, until now, required the membrane to be both boun...
Ion flux through membrane channels is passively driven by the electrochemical potential differences ...