Thresholds and Plateaus in the Hodgkin-Huxley Nerve Equations

doi:10.1085/jgp.43.5.867

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ARTICLE

Thresholds and Plateaus in the Hodgkin-Huxley Nerve Equations

Richard Fitzhugh ¹

¹ From the National Institutes of Health, Bethesda.

Phase space methods and an analog computer are used to analyzethe Hodgkin-Huxley non-linear differential equations for thesquid giant axon membrane. V is the membrane potential, m theNa⁺ activation, h the Na⁺ inactivation, and n the K⁺ activation.V and m change rapidly, relative to h and n. The (V, m) phaseplane of a reduced system of equations, with h and n held constantat their resting values, has three singular points: a stableresting point, a threshold saddle point, and a stable excitedpoint. When h and n are allowed to vary, recovery and refractorinessresult from the movement with subsequent disappearance of thethreshold and excited points. Multiplying the time constantof n by 100 or more, and that of h by one-third, reproducesthe experimental plateau action potentials obtained with tetraethylammoniumby Tasaki and Hagiwara, including the phenomena of abolitionand of refractoriness of the plateau duration. The equationshave, transiently, two stable states, as found in the real axonby these authors. Since the theoretical membrane conductancecurves differ significantly from the experimental ones, furtherexperimental analysis of ionic currents with tetraethylammoniumis needed to decide whether the Hodgkin-Huxley model can begeneralized to explain these experiments completely.

Submitted on September 15, 1959

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