Effects of cellular geometry on current flow during a propagated action potential.

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Effects of cellular geometry on current flow during a propagated action potential.

R W Joyner, M Westerfield and J W Moore

ABSTRACT

An impulse propagating in a cell with nonuniform geometry seesan increased electrical load at regions of increasing diameteror at branch points with certain morphologies. We present heretheoretical and experimental studies on the changes in membranecurrent and axial current associated with diameter changes.The theoretical studies were done with numerical solutions forcable equations that were generalized to include a varying diameter;the Hodgkin-Huxley equations were used to represent the membraneproperties. The experimental studied were done using squid axonswith the axial insertion of platinized platinum wires to createa localized region of increased electrical load. As an actionpotential approaches a region of increased electrical load,the action potential amplitude and rate of rise decrease, butthere is a marked increase in the magnitude of the inward sodiumcurrent. The time integrals of the inward and outward currentsare not constant along the fiber and indicate net inward chargemovement at regions subjected to an increased electrical load.Changes in the waveform of the axial current at such a regionhelp to explain the temperature dependence of propagation failureat regions of increasing electrical load.

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