Electrical excitation of the acoustically sensitive auditory nerve: single-fiber responses to electric pulse trains

• Published in: Journal of the Association for Research in Otolaryngology Vol. 7; no. 3; pp. 195 - 210
• Main Authors: Miller, Charles A, Abbas, Paul J, Robinson, Barbara K, Nourski, Kirill V, Zhang, Fawen, Jeng, Fuh-Cherng
• Format: Journal Article
• Language: English
• Published: United States Springer Nature B.V 01.09.2006; Springer-Verlag
• Subjects: Animals; Auditory Threshold - physiology; Cats; Cochlear Implants; Cochlear Nerve - physiology; Deafness - chemically induced; Deafness - physiopathology; Deafness - therapy; Hair Cells, Auditory - physiology; Humans; Models, Animal; Signal Transduction - physiology
• ISSN: 1525-3961; 1438-7573
• DOI: 10.1007/s10162-006-0036-9

Nearly all studies on auditory-nerve responses to electric stimuli have been conducted using chemically deafened animals so as to more realistically model the implanted human ear that has typically been profoundly deaf. However, clinical criteria for implantation have recently been relaxed. Ears with "residual" acoustic sensitivity are now being implanted, calling for the systematic evaluation of auditory-nerve responses to electric stimuli as well as combined electric and acoustic stimuli in acoustically sensitive ears. This article presents a systematic investigation of single-fiber responses to electric stimuli in acoustically sensitive ears. Responses to 250 pulse/s electric pulse trains were collected from 18 cats. Properties such as threshold, dynamic range, and jitter were found to differ from those of deaf ears. Other types of fiber activity observed in acoustically sensitive ears (i.e., spontaneous activity and electrophonic responses) were found to alter the temporal coding of electric stimuli. The electrophonic response, which was shown to greatly change the information encoded by spike intervals, also exhibited fast adaptation relative to that observed in the "direct" response to electric stimuli. More complex responses, such as "buildup" (increased responsiveness to successive pulses) and "bursting" (alternating periods of responsiveness and unresponsiveness) were observed. Our findings suggest that bursting is a response unique to sustained electric stimulation in ears with functional hair cells.