Subthreshold Behavior and Phenomenological Impedance of the Squid Giant Axon

doi:10.1085/jgp.55.4.497

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Subthreshold Behavior and Phenomenological Impedance of the Squid Giant Axon

A. Mauro ¹, F. Conti ¹, F. Dodge ¹, and R. Schor ¹

¹ From The Rockefeller University, New York 10021, Laboratory of Cybernetics and Biophysics of the CNR, Camogli, Italy, and the IBM Watson Research Center, Yorktown Heights, New York 10598

The oscillatory behavior of the cephalopod giant axons in responseto an applied current has been established by previous investigators.In the study reported here the relationship between the familiar"RC" electrotonic response and the oscillatory behavior is examinedexperimentally and shown to be dependent on the membrane potential.Computations based on the three-current system which was inferredfrom electrical measurements by Hodgkin and Huxley yield subthresholdresponses in good agreement with experimental data. The pointwhich is developed explicitly is that since the three currents,in general, have nonzero resting values and two currents, the"Na" system and the "K" system, are controlled by voltage-dependenttime-variant conductances, the subthreshold behavior of thesquid axon in the small-signal range can be looked upon as arisingfrom phenomenological inductance or capacitance. The total phenomenologicalimpedance as a function of membrane potential is derived bylinearizing the empirically fitted equations which describethe time-variant conductances. At the resting potential theimpedance consists of three structures in parallel, namely,two series RL elements and one series RC element. The true membranecapacitance acts in parallel with the phenomenological elements,to give a total impedance which is, in effect, a parallel R,L, C system with a "natural frequency" of oscillation. At relativelyhyperpolarized levels the impedance "degenerates" to an RC system.

Submitted on June 14, 1969

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