Accessing the tonotopic organization of the ventral cochlear nucleus by intranuclear microstimulation

Accessing the tonotopic organization of the ventral cochlear nucleus by intranuclear microstimulation

This study is part of a program to develop an auditory prosthesis for the profoundly deaf, based on multichannel microstimulation in the cochlear nucleus. The functionality of such a device is dependent on its ability to access the tonotopic axis of the human ventral cochlear nucleus in an orderly f...

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Bibliographic Details
Published in:IEEE transactions on rehabilitation engineering Vol. 6; no. 4; pp. 391 - 399
Main Authors: McCreery, D.B., Shannon, R.V., Moore, J.K., Chatterjee, M.
Format: Journal Article
Language:English
Published: United States IEEE 01-12-1998
Subjects:
Acoustic arrays
Action Potentials
Animals
Audition
Auditory system
Cats
Cochlear Implants
Cochlear Nucleus - anatomy & histology
Cochlear Nucleus - physiology
Deafness
Electric Stimulation
Electrodes
Evoked Potentials
Female
Functional assessment
Humans
Implants (surgical)
Male
Microelectrodes
Neurons
Neurophysiology
Prosthetics
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Summary:This study is part of a program to develop an auditory prosthesis for the profoundly deaf, based on multichannel microstimulation in the cochlear nucleus. The functionality of such a device is dependent on its ability to access the tonotopic axis of the human ventral cochlear nucleus in an orderly fashion. In these studies, the authors utilized the homologies between the human and feline ventral cochlear nuclei and the known tonotopic organization of the central nucleus of the inferior colliculus (IC). In anesthetized cats, stimuli were delivered to three or four locations along the dorsal-to-ventral axis of the posteroventral cochlear nucleus (PVCN), and for each stimulus location, the authors recorded the multiunit neuronal activity and the field potentials at 20 or more locations along the dorsolateral-ventromedial (tonotopic) axis of the IC. The current source-sink density (CSD), which delimits regions of neuronal activity, was computed from the sequence of field potentials recorded along this axis. The multiunit activity and the CSD analysis both showed that the tonotopic organization of the PVCN can be accessed in an orderly manner by intranuclear microstimulation in several regions of the PVCN, using the range of stimulus pulse amplitudes that have been shown in previous studies to be noninjurious during prolonged intranuclear microstimulation via chronically implanted microelectrodes. The authors discuss the applicability of these findings to the design of clinical auditory prostheses for implantation into the human cochlear nucleus.
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ISSN:1063-6528
1558-0024
DOI:10.1109/86.736153