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A surface recorded vestibular evoked response to acceleration in cats

Published online by Cambridge University Press:  27 May 2011

J. Elidan ,
H. Sohmer  and
M. Nitzan
J. Elidan
Affiliation:
(Jerusalem, Israel)
H. Sohmer
Affiliation:
(Jerusalem, Israel)
M. Nitzan
Affiliation:
(Jerusalem, Israel)
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Abstract

Vestibular evoked responses to repetitive acceleration stimuli were recorded by skin electrodes in cats using filtering and averaging techniques. The response is made up of six—eight waves during the first 10 msec following the stimulus. Longer latency myogenic responses had large amplitude and disappeared following the paralysis of the animals. The neurogenic waves disappeared after the destruction of both inner ears or the excision of both eighth nerves and following death. Destruction of the inner ear, or excision of the VIIIth nerve on one side leads to response patterns of excitation vs. inhibition when appropriate excitatory and inhibitory acceleration stimuli are applied. The possible generators of the evoked responses are discussed in the light of the physiology of the vestibular pathways, and the results of the present experiments suggest that the generators of the first and second waves are the vestibular nerve and vestibular nucleus respectively. In addition, the vestibular evoked response seemed to be more sensitive to ischemia of the brain than the auditory brainstem evoked response and may therefore reflect better changes in brain function.

Type
Session I. Mechanics of Tinnitus - Theory and Fact (Chairman: J. Vernon)
Information
The Journal of Laryngology & Otology , Volume 98 , supplement S9: Proceedings of the II International Tinnitus Seminar. New York, 10 and 11 June 1983 , June 1984 , pp. 111 - 119
Copyright
Copyright © JLO (1984) Limited 1984

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References

1.Cody, D. T. and Bickford, R. G. (1969) Averaged evoked myogenic responses in normal man. Laryngoscope, 79: 400416.CrossRefGoogle ScholarPubMed
2.Cody, D. T. R., Jackson, J. L., Walker, J. C. and Bickford, R. G. (1964) Averaged Evoked Myogenic and Cortical potentials to sound in Man. Annals of Otology, Rhinology and Laryngology, 73: 763777.CrossRefGoogle ScholarPubMed
3.Elidan, J., Sohmer, H. and Nizan, M. (1982) Recording of short latency vestibular evoked potentials to acceleration in rats by means of skin electrodes. Electroenceph. Clinical Neurophysiology, 53: 501515.CrossRefGoogle ScholarPubMed
4.Goldberg, J. M. and Fernandez, C. (1971) Physiology of peripheral neurons innvervating semicircular canal of the squirrel monkey. I. Resting discharge and response to constant angular acceleration. Journal of Neurophysiology, 34: 635660.CrossRefGoogle Scholar
5.Precht, W and Shimazu, H. (1965) Functional connections of tonic and kinetic vestibular neurons with primary vestibular afferents. Journal of Neurophysiology, 28: 1014–1028.CrossRefGoogle ScholarPubMed
6.Precht, W., Llina'S, R. and Clarke, M. (1971) Physiological responses of frog vestibular fibers to horizontal angular rotation. Experimental Brain Research, 13: 378407.CrossRefGoogle ScholarPubMed
7.Shimazu, H. and Precht, W. (1965) Tonic and kinetic responses of cat's vestibular neurons to horizontal angular acceleration. Journal of Neurophysiology, 28: 9911013.CrossRefGoogle ScholarPubMed
8.Shimazu, H. and Precht, W. (1966) Inhibition of central vestibular neurons from the contralateral labyrinth and its mediating pathway. Journal of Neurophysiology, 29: 467492.CrossRefGoogle ScholarPubMed