STEPS IN THE PRODUCTION OF MOTONEURON SPIKES

doi:10.1085/jgp.40.5.735

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ARTICLE

STEPS IN THE PRODUCTION OF MOTONEURON SPIKES

M. G. F. Fuortes ¹, K. Frank ¹, and Mary C. Becker ¹

¹ From the Department of Neurophysiology, Walter Reed Army Institute of Research, Walter Reed Army Medical Center, Washington, D. C., and National Institute of Neurological Diseases and Blindness, National Institutes of Health, Public Health Service, United States Department of Health, Education, and Welfare, Bethesda

1. Spikes evoked in spinal motoneurons by antidromic stimulationnormally present an inflection in their rising phase. A similarinflection is present in spikes evoked by direct stimulationwith short pulses.

2. In either case the inflection becomesless prominent if the motoneuron membrane is depolarized andmore prominent when it is hyperpolarized. Both antidromic anddirect spikes may fall from the level of the inflection thusevoking a "small spike" only if sufficient hyperpolarizationis applied. Similar events occur when antidromic or direct spikesare evoked in the aftermath of a preceding spike.

3. Spikesevoked by direct stimuli applied shortly after firing of a "smallspike" may also become partially blocked at a critical stimulusinterval. At shorter intervals, however, spike size again increasesand no inflection can be detected in the rising phase.

4. Whena weak direct stimulus evokes a small spike only, a strongerstimulus may evoke a full spike. Curves of the strength of thestimuli required for eliciting small or full spikes have beenconstructed in a number of conditions.

5. To explain the resultsit is assumed that threshold of the major portions of the somamembrane is higher than the threshold of the axon, the transitionoccurring over a finite area near the axon hillock. Followingantidromic or direct stimulation, soma excitation is then initiatedin the region of the axon hillock. Spread of activity towardsthe soma occurs at first slowly and with low safety factor.At this stage block may be easily evoked. Safety factor forpropagation increases rapidly as the growing impulse involveslarger and larger areas of the soma membrane so that, once thecritical areas are excited, activation of the remaining portionsof the soma membrane will suddenly occur.

Submitted on November 29, 1956

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