Hearing research
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To investigate the origin of non-auditory fibres in the apical area of the avian cochlear ganglion, we recorded from nerve fibres in the young chick (87% of animals were aged between 5 and 10 days post-hatching). After characterization of their spontaneous activity patterns and, if present, their responses to sound, some fibres were stained with cobalt-ion injections and traced to their peripheral terminals. All stained fibres which were traced to the lagenar macula (N = 13) were non-auditory. ⋯ All fibres that responded in any way to sound were irregularly spontaneously active. Three fibres, two of which only responded to sound with phase-coupling, innervated several hair cells in the apical, abneural region of the basilar papilla. Two other fibres traced to the basilar papilla are of previously undescribed types.
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The major focus of this study was to define the effects of chronic intracochlear electrical stimulation (ICES) on single unit responses in the inferior colliculus from three experimental groups: 1) normal adults 2) neonatally-deafened/unstimulated adults; and 3) neonatally-deafened/chronically stimulated adults. The major findings include: 1) IC neurons in normal adults showed a diversity of perstimulus responses to ICES which were qualitatively similar to those evoked by acoustic stimuli. They responded with: an onset burst, a sustained discharge, a decrease in their spontaneous activity, or a strong post-stimulus response. ⋯ Their perstimulus response latencies were significantly shorter, their late response latencies were significantly longer, and the frequency of occurrence of inhibitory and late responses were significantly higher. From these results we conclude that the responses to intracochlear electrical stimulation are directly comparable to those observed following normal acoustic stimulation; that development of cochleotopic organization of the inferior colliculus is not affected by the almost complete lack of normal acoustic input experienced by neonatally deafened animals; and that the basic response properties of IC units are likewise unaffected by neonatal deafening. Moreover, the results suggest that, although the limited regime of electrical stimulation employed in these studies produced no major qualitative distortions in the perstimulus response patterns of IC neurons, it did result in some quantitative changes in those responses.
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Ten newborn kittens were deafened by systemic administration of neomycin sulfate. Profound hearing losses were documented by ABR and FFR (500 Hz) testing. At 9-17 weeks of age, the young deafened cats were unilaterally implanted with a multichannel scala tympani electrode. ⋯ In more apical regions there was no significant difference between the stimulated and control cochleas. The mechanisms underlying this selective conservation of spiral ganglion neurons induced by chronic intracochlear electrical stimulation are uncertain. Since no comparable chronic stimulation studies have been conducted in adults, it is not known whether similar conservation effects could be induced in mature animals.
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Four newborn kittens were deafened by daily intramuscular injections of neomycin sulfate, beginning the day after birth and continuing for 14-16 days. At 10-16 weeks of age the deaf kittens were implanted unilaterally with a four wire intracochlear electrode array. The animals were stimulated daily (starting at 13-18 weeks of age), for a period of one hour, at 6 dB above the electrically evoked auditory brainstem response threshold. ⋯ These changes were observed in both cochlear nuclei (ipsilateral to both stimulated and unstimulated ears) of the deafened animals. With the measures employed, no significant difference was demonstrated in comparisons between the deafened/unstimulated and the deafened/stimulated cochlear nuclei. That is, no reversal of the profound effects of deafening was observed in the cochlear nuclei as a consequence of chronic intracochlear electrical stimulation which was begun 11 to 16 weeks after deafening.
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We have examined changes in the orientation of stereociliary bundles of hair cells in the cochlear sensory epithelium that occur during normal embryonic development and during the regeneration of hair cells that follows acoustic trauma. At the time when hair cell surfaces become recognizable in the embryonic cochlea, the bundles of stereocilia exhibit a range of orientations, as indicated by the position of the kinocilium and later, by the location of the tallest row of stereocilia. With time, the orientations of bundles on neighboring hair cells become more uniform, a condition that is maintained in the adult. ⋯ A common mechanism may guide reorientation both during embryonic development and during regeneration. Observations in living cochleae indicate that differentiating stereociliary bundles establish asymmetric linkages to the extracellular matrix of the developing tectorial membrane. During the growth of the tectorial membrane, its progressive extension across the surface of the sensory epithelium may exert traction forces through those asymmetric linkages that pull the bundles of the hair cells into uniform alignment.