• R K Shepherd, J H Baxi, and N A Hardie.
• Human Communications Research Centre, Department of Otolaryngology, The University of Melbourne, Parkville, Victoria 3052, Australia.
• J. Neurophysiol. 1999 Sep 1; 82 (3): 1363-80.

AbstractResponse properties of neurons in the inferior colliculus (IC) were examined in control and profoundly deafened animals to electrical stimulation of the auditory nerve. Seven adult cats were used: two controls; four neonatally deafened (2 bilaterally, 2 unilaterally); and one long-term bilaterally deaf cat. All control cochleae were deafened immediately before recording to avoid electrophonic activation of hair cells. Histological analysis of neonatally deafened cochleae showed no evidence of hair cells and a moderate to severe spiral ganglion cell loss, whereas the long-term deaf animal had only 1-2% ganglion cell survival. Under barbiturate anesthesia, scala tympani electrodes were implanted bilaterally and the auditory nerve electrically stimulated using 100 micros/phase biphasic current pulses. Single-unit (n = 419) recordings were made through the lateral (LN) and central (ICC) nuclei of the IC; responses could be elicited readily in all animals. Approximately 80% of cells responded to contralateral stimulation, whereas nearly 75% showed an excitatory response to ipsilateral stimulation. Most units showed a monotonic increase in spike probability and reduction in latency and jitter with increasing current. Nonmonotonic activity was seen in 15% of units regardless of hearing status. Neurons in the LN exhibited longer latencies (10-25 ms) compared with those in the ICC (5-8 ms). There was a deafness-induced increase in latency, jitter, and dynamic range; the extent of these changes was related to duration of deafness. The ICC maintained a rudimentary cochleotopic organization in all neonatally deafened animals, suggesting that this organization is laid down during development in the absence of normal afferent input. Temporal resolution of IC neurons was reduced significantly in neonatal bilaterally deafened animals compared with acutely deafened controls, whereas neonatal unilaterally deafened animals showed no reduction. It would appear that monaural afferent input is sufficient to maintain normal levels of temporal resolution in auditory midbrain neurons. These experiments have shown that many of the basic response properties are similar across animals with a wide range of auditory experience. However, important differences were identified, including increased response latencies and temporal jitter, and reduced levels of temporal resolution.

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