The electrodiffusion model presented in the previous paper, which specifically excludes ion-ion interactions, is analyzed for the ratio of one-way fluxes (flux ratio) as a function of the ionic driving force across the membrane. Significant deviations from the behavior expected on the basis of the Ussing relation are found. These are sufficient to explain the “nonindependent” ion movement noted in some biological flux ratio data. One-way fluxes are dependent on the ionic concentration on both sides of the membrane. The coupling of these fluxes to ionic concentrations comes from the dependence of ionic mobility and the diffusion coefficient on the equilibrium potential. It is concluded that nonindependent behavior in experimental data is not...
When a current is passed through a membrane system, differences in transport numbers between the mem...
An electrodiffusion model for plasma membrane ion transport, which takes into account the influence ...
The formalisms of irreversible thermodynamics are used to describe multi-ionic nonconvective flow th...
The electrodiffusion model presented in the previous paper, which specifically excludes ion-ion inte...
The unidirectional flux of an ionic species may occur because of several mechanisms such as active t...
Ions crossing biological membranes are described as a concentration of charge flowing through a sele...
We have examined the steady-state and time-dependent electrical properties of a model membrane syste...
The equation presented in the previous paper for steady-state membrane ionic current as a function o...
The usual assumption in treating the diffusion of ions in an electric field has been that the moveme...
Ion flux through membrane channels is passively driven by the electrochemical potential differences ...
The movement of ions in the aqueous medium as they approach the mouth (radius a) of a conducting mem...
The model of the excitable membrane assumes common channels for Na+ and K+; the two ion species inte...
The behavior of a multiply-occupied cation-selective channel has been computed by Brownian dynamics....
In a previous paper (Jakobsson, E., and S. W. Chiu. 1987. Biophys. J. 52:33–46), we presented the st...
A model for ion movement through specialized sites in the plasma membrane is presented and analyzed ...
When a current is passed through a membrane system, differences in transport numbers between the mem...
An electrodiffusion model for plasma membrane ion transport, which takes into account the influence ...
The formalisms of irreversible thermodynamics are used to describe multi-ionic nonconvective flow th...
The electrodiffusion model presented in the previous paper, which specifically excludes ion-ion inte...
The unidirectional flux of an ionic species may occur because of several mechanisms such as active t...
Ions crossing biological membranes are described as a concentration of charge flowing through a sele...
We have examined the steady-state and time-dependent electrical properties of a model membrane syste...
The equation presented in the previous paper for steady-state membrane ionic current as a function o...
The usual assumption in treating the diffusion of ions in an electric field has been that the moveme...
Ion flux through membrane channels is passively driven by the electrochemical potential differences ...
The movement of ions in the aqueous medium as they approach the mouth (radius a) of a conducting mem...
The model of the excitable membrane assumes common channels for Na+ and K+; the two ion species inte...
The behavior of a multiply-occupied cation-selective channel has been computed by Brownian dynamics....
In a previous paper (Jakobsson, E., and S. W. Chiu. 1987. Biophys. J. 52:33–46), we presented the st...
A model for ion movement through specialized sites in the plasma membrane is presented and analyzed ...
When a current is passed through a membrane system, differences in transport numbers between the mem...
An electrodiffusion model for plasma membrane ion transport, which takes into account the influence ...
The formalisms of irreversible thermodynamics are used to describe multi-ionic nonconvective flow th...