Nonlinear Electrical Effects in Lipid Bilayer Membranes: II. Integration of the Generalized Nernst-Planck Equations

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Biophysical Journal 9: 1160-1170 (1969)
© 1969 the Biophysical Society

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Nonlinear Electrical Effects in Lipid Bilayer Membranes

II. Integration of the Generalized Nernst-Planck Equations

B. Neumcke and P. Läuger

ABSTRACT

In this paper the ion transport across a thin lipid membraneis treated using a generalized form of the Nernst-Planck equations.An additional term is introduced into the flux equations toaccount for the image force acting on the ion. As the membranethickness is of the same order of magnitude as the range ofthe image forces, the potential energy of the ion in the membraneis strongly dependent on position. The integration of the fluxequations leads to a general expression for the integral membraneconductance ${lambda}$ as a function of the voltage u. The ratio ${lambda}$ (u)/ ${lambda}$ ₀( ${lambda}$ ₀ = membrane conductance in the limit u $->$ 0) depends on thedielectric constant and the thickness of the membrane, but isindependent of the ionic radius. When the numerical values ofthe potential energy function, as calculated by the method ofelectrical images, are inserted into the expression for ${lambda}$ (u)/ ${lambda}$ ₀,a strongly non-linear current-voltage characteristic is obtained.The theoretical current-voltage curve agrees satisfactorilywith the experimental data at a low ionic strength and at lowvoltages; at higher voltages the observed membrane conductanceexceeds the predicted value.

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