Your search keyword '"John M. Gibson"' showing total 3 results

1. Functional development of mechanoreceptive neurons innervating the glabrous skin in postnatal kittens

Author

Ralph E. Beitel, John M. Gibson, and Wally Welker

Subjects

Refractory period, Neural Conduction, Action Potentials, Nerve fiber, Biology, Stimulus (physiology), Nerve conduction velocity, Ganglia, Spinal, Electrical conduction, Forelimb, medicine, Animals, Glabrous skin, Neurons, Afferent, Molecular Biology, Skin, Foot, General Neuroscience, Thermoreceptors, Anatomy, Electric Stimulation, Functional development, medicine.anatomical_structure, Animals, Newborn, Receptive field, Cats, Neurology (clinical), Mechanoreceptors, Neuroscience, Developmental Biology

Abstract

We studied single units innervating the glabrous forepaw skin of 35 domestic kittens ranging in age from 1 to 52 postnatal days. Three aspects of coding were emphasized: (a) size and force thresholds of receptive fields, (b) time course of recovery between stimulus presentations, and (c) electrical conduction properties of the afferent nerve fibers. Receptive field (RF) size and force thresholds were (a) positively correlated with age for palmar but not digital RFs, and (b) were significantly larger on palm than on digits. Unit responsiveness was highly dependent on intertrial interval, complete recovery requiring at least 30 sec. Conduction velocity increased more rapidly than nerve fiber length, thus conduction time decreased with age. Refractory period decreased with age, but the conduction velocities of sequential spikes were proportional, regardless of age. These changes which we observed can more readily be ascribed to alterations of the mechanical properties of skin and conduction properties of nerve fibers than to changes in the coding mechanisms themselves.

Published

1977

2. Trigeminocerebellar mossy fiber branching to granule cell layer patches in the rat cerebellum

Author

Jeffrey Kassel, D.C. Woolston, and John M. Gibson

Subjects

Refractory Period, Electrophysiological, Branching (polymer chemistry), Trigeminal Nuclei, Nerve Fibers, Cerebellum, medicine, Animals, Trigeminal Nerve, Axon, Evoked Potentials, Molecular Biology, Neurons, Brain Mapping, Chemistry, General Neuroscience, Granule cell, Axons, Electric Stimulation, Rats, Antidromic, Electrophysiology, medicine.anatomical_structure, Touch, Receptive field, Face, Female, Neurology (clinical), Neuron, Mechanoreceptors, Nucleus, Neuroscience, Developmental Biology

Abstract

Recent micromapping studies of tactile areas in rat cerebellum have revealed a spatially precise mosaic of granule cell layer areas termed ‘patches’, with multiple patches on several folia resulting in multiple representations of the same body part. The research reported in the present paper tested the hypothesis that trigeminocerebellar mossy fiber branching is patch-related, so that collaterals terminate only within the boundaries of one or more of the tiny (often less than 1 sq. mm) patches having similar receptive fields. This hypothesis was supported by 3 separate series of electrophysiological physiological experiments: (1) electrical stimulation in a patch resulted in short latency, low threshold responses confined within the boundaries of a second patch having a similar receptive field; (2) antidromic collison tests demonstrated that collaterals of axons originating in nucleus interpolaris reach pairs of patches with similar receptive fields; and (3) micromapping of the area from which a particular interpolaris neuron could be antidromically activated revealed that local terminal branching of a given mossy fiber axon appeared to be confined within the boundaries of a single patch. Together these results indicate that trigeminocerebellar mossy fiber branching is related to the fractured somatotopical organization of the granule cell layer. Possible functional implications of such mossy fiber branching are discussed.

Published

1981

3. Diversity of coding profiles of mechanoreceptors in glabrous skin of kittens

Author

John M. Gibson, Ralph E. Beitel, and Wally Welker

Subjects

Time Factors, Discharge data, Neural Conduction, Stimulus (physiology), Histogram, Ganglia, Spinal, Forelimb, Glabrous skin, Animals, Molecular Biology, Mathematics, Skin, Communication, business.industry, General Neuroscience, Interstimulus interval, Response analysis, Age Factors, Adaptation, Physiological, Electrophysiology, Amplitude, Animals, Newborn, Receptive field, Cats, Neurology (clinical), business, Biological system, Mechanoreceptors, Developmental Biology

Abstract

Summary We examined stimulus-response (S-R) profiles of 35 single mechanoreceptive afferent units having small receptive fields in glabrous forepaw skin of 24 anesthetized domestic kittens. Single unit activity was recorded with tungsten microelectrodes from cervical dorsal root ganglia. The study was designed to be as quantitatively descriptive as possible. We indented each unit's receptive field with a broad battery of simple, carefully controlled stimuli whose major parameters, including amplitude, velocity, acceleration, duration, and interstimulus interval were systematically varied. Stimuli were delivered by a small probe driven by a feedback-controlled axial displacement generator. Single unit discharge data were analyzed by a variety of direct and derived measures including dot patterns, peristimulus histograms, instantaneous and mean instantaneous firing rates, tuning curves, thresholds for amplitude and velocity, adaptation rates, dynamic and static sensitivities, and others. We found that with respect to any of the S-R transactions examined, the properties of our sample of units were continously and broadly distributed. Any one unit might exhibit either a slow or rapid rate of adaptation, or might superficially appear to preferentially code a single stimulus parameter such as amplitude or velocity. But when the entire range of responsiveness of units to the entire stimulus battery was surveyed by a variety of analytic techniques, we were unable to find any justifiable basis for designation of discrete categories of S-R profiles. Intermediate response types were always found, and in general, all units were both broadly tuned and capable of responding to integrals of several stimulus parameters. Our data argue against the usefulness of evaluating a unit's S-R coding capabilities by means of a limited set of stimulation or response analysis procedures.

Published

1975