Theory of negative capacitance in membrane impedance measurements

Electrical tolerance (breakdown) of the Chara corallina plasmalemma: II. Inductive property of membrane and effects of pHo and impermeable monovalent cations on breakdown phenomenon

Changes in the chord conductance G and the membrane electromotive force Em in the so-called breakdown region of large negative potential of the Chara plasmalemma were analyzed in more detail. In addition to the increase in G, the voltage sensitivity of the change in G increased, which was the cause of marked inductive current in the breakdown region. The break-down potential, defined as a critical potential at which both low and high slope conductances of the I-Vm relationship cross, almost coincided with the potential at which an inductive current began to appear. This breakdown potential level changed with pHo in a range between 5 and 9. The Chara plasmalemma was electrically most tolerant around pHo 7. In some cells Em shifted to a positive level as large as +50 approximately +70 mV during the breakdown phenomenon. Such a large positive shift of Em is caused mainly by the increase in conductance of Cl- and partly Ca2+ and K+.

Analysis of the diffusion theory of negative capacitance: the role of K+ and the unstirred layer thickness

The diffusion theory of negative capacitance is extended to take into account potassium transport as well as proton or hydroxyl transport. It is shown that both the capacitance spectrum and the frequency at which the capacitance is zero can be used to experimentally test the theory. The effects of the fraction of potassium current, membrane conductance, NaCl concentration, and unstirred layer thickness on these two characteristics is investigated. Maximum negative capacitance can be obtained when the current flowing through the membrane is mainly carried by protons, the membrane conductance is high, the solution conductivity is low, and the unstirred layer thickness is large. The effect of a dominant hydroxyl transport in place of a proton transport is also discussed. We suggest simple experiments to test the theory on Characeaen plant cells.