Z. J. Koles scite author profile

SUMMARY1. The theoretical effects ofdemyelination on conduction ofa propagated impulse have been examined in a computer simulated myelinated nerve fibre. Demyelination was simulated by increasing the capacitance and conductance of the myelin sheath of individual internodes or parts of internodes.2. Internodal conduction time increased as myelin thickness was decreased. The increase in internodal conduction time became more precipitous as the myelin became thinner. Propagation continued past a single demyelinated internode until myelin thickness was uniformly reduced to less than 2-7 % of normal myelin thickness.3. Paranodal demyelination was more effective in slowing impulse conduction than was uniform demyelination of an entire internode with an equivalent rise in overall internodal capacitance and conductance.4. The effects on conduction of demyelination of two adjacent internodes or of two internodes separated by a normal internode were more than the sum of the effects of demyelination of each internode individually.5. Propagation across a severely demyelinated internode was blocked with an increase in internal sodium concentration which had a trivial effect on conduction in a normal fibre.6. Propagation across a severely demyelinated internode was blocked

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Conduction velocity in myelinated nerve fibres of Xenopus laevis

Hutchinson¹,

Koles²,

Smith³

1970

The Journal of Physiology

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3. The slope of the conduction velocity-temperature relationship was directly proportional to the diameter of the nerve fibre.4. The form of the conduction velocity-temperature relationship was determined by numerical solution ofthe Frankenhaeuser-Huxley equations for the case of a propagated action potential. The coniputation predicted that conduction velocity is a linear function of temperature over the range studied.

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Mean velocity of optically detected intraaxonal particles measured by a cross-correlation method

Smith¹,

Koles²

1976

Can. J. Physiol. Pharmacol.

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A method which uses by the cross correlation of optical signals is described for the determination of the mean velocity of somatopetally moving particles within nerve fibers. The method was validated by simulation experiments and by comparing the results with those obtained by averaging collections of velocities of individual particles. The significant contribution of the method is that it allows objective and rapid serial evaluation of mean particle velocity within individual nerve fibers with good accuracy and precision. A series of results from normal myelinated nerve fibers from Xenopus laevis is presented. Considerable variation (up to 50%) in mean velocity was found between individual nerve fibers. The mean of all determinations indicates that the mean velocity of somatopetally moving particles in axons with diameters greater than 10mum is in the region of 1.14 mum/s at a temperature of 22-24 degrees C. The findings are compared with small collection of such determinations which have been reported in the literature.

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Z. J. Koles

Myelinated nerve fibers: computed effect of myelin thickness on conduction velocity

A computer simulation of conduction in demyelinated nerve fibres

Conduction velocity in myelinated nerve fibres of Xenopus laevis

Mean velocity of optically detected intraaxonal particles measured by a cross-correlation method

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