The passive electrical properties of the membrane of a molluscan neurone

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J Physiol Vol 227, Issue 1 pp 35-49
Copyright © 1972 by The Physiological Society

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The passive electrical properties of the membrane of a molluscan neurone

A. L. F. Gorman and Maurizio Mirolli

1. The passive electrical properties of the membrane of thegastrooesophageal giant neurone (G cell) of the marine mollusc,Anisodoris nobilis were studied with small current steps.

2. The membrane transient response can be fitted with a theoreticalcurve assuming as a model for the cell a sphere (soma) connectedto a cable (axon). The axo-somatic conductance ratio ( ${rho}$ ), determinedby applying this model, is large (approximately 5) and the membranetime constant ( ${tau}$ ) is long (approximately 1 sec).

3. When the actual surface area of the cell, corrected for surfaceinfoldings, and the spread of current along its axon is takeninto account, the electrical measurements imply a specific resistanceof the membrane of approximately 1·0 M ${Omega}$ .cm².

4. Estimates of specific membrane capacity, either from measurementsof the initial portion of the membrane transient or from theratio of the time constant to the specific membrane resistanceare close to the value of 1 µF/cm² expected for biologicalmembranes.

5. Thus, our measurements of specific capacitance, time constant,length constant and axo-somatic conductance ratio all indicatethat the value found for the specific membrane resistance ofthe G cell, while unexpectedly large, is valid.

6. The magnitude of this value suggests that the conductance(permeability) of its membrane to ions is much smaller thanthat previously assumed for nerve membranes; this small conductancemay be related to the larger surface-to-volume ratio of theG cell.

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