2006
DOI: 10.1007/s10162-006-0036-9
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Electrical Excitation of the Acoustically Sensitive Auditory Nerve: Single-Fiber Responses to Electric Pulse Trains

Abstract: 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 Bresidualâ coustic 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 sensi… Show more

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Cited by 53 publications
(89 citation statements)
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“…In the absence of hair cells, the auditory nerve is normally silent, but when hair cells are present, there is spontaneous activity, which can affect the responses of the nerve to electrical stimulation (Wilson 1997;Haenggeli et al 1998;Hu et al 2003;Miller et al 2006). In our study, the presence or absence of spontaneous activity in the auditory nerve was assessed by recording ensemble activity (Dolan et al 1990;Searchfield et al 2004) from the cochlear implant electrodes in all group I animals and in four group II animals.…”
Section: Methodsmentioning
confidence: 99%
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“…In the absence of hair cells, the auditory nerve is normally silent, but when hair cells are present, there is spontaneous activity, which can affect the responses of the nerve to electrical stimulation (Wilson 1997;Haenggeli et al 1998;Hu et al 2003;Miller et al 2006). In our study, the presence or absence of spontaneous activity in the auditory nerve was assessed by recording ensemble activity (Dolan et al 1990;Searchfield et al 2004) from the cochlear implant electrodes in all group I animals and in four group II animals.…”
Section: Methodsmentioning
confidence: 99%
“…However, it is probable that surviving hair cells and related cochlear elements also directly affect electrical hearing. Cochlear implant function in hearing versus deaf ears has been studied in some detail at the neurophysiological level (Moxon 1971;van den Honert and Stypulkowski 1984;Shepherd and Javel 1997;Miller et al 2006), but we know less about the effects of preserved acoustic hearing on the responses to electrical stimulation at the psychophysical perceptual level. Thus, studies exploring the effects of preserving acoustic hearing on the perception of cochlear implant electrical stimulation are needed.…”
Section: Introductionmentioning
confidence: 99%
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“…In spite of this, the rate of vesicle fusion decreases on a time scale similar to that of short-term adaptation (Moser and Beutner 2000;Spassova et al 2004), and refilling of the emptied vesicle pool is kinetically similar to recovery from this adaptation ). Adaptation resulting from direct electrical stimulation of the auditory nerve (i.e., bypassing the hair cell) contrasts with acoustically evoked adaptation in that it is mild and seen only under certain conditions (Parkins 1989;Javel 1996;Miller et al 2006). Miller et al (2006) also note that adaptation to electric stimuli can be reduced by increasing the level of stimulation, a phenomenon not seen with acoustic stimulation.…”
Section: Adaptation Across the Tonotopic Axis Of The Basilar Papillamentioning
confidence: 99%
“…Adaptation resulting from direct electrical stimulation of the auditory nerve (i.e., bypassing the hair cell) contrasts with acoustically evoked adaptation in that it is mild and seen only under certain conditions (Parkins 1989;Javel 1996;Miller et al 2006). Miller et al (2006) also note that adaptation to electric stimuli can be reduced by increasing the level of stimulation, a phenomenon not seen with acoustic stimulation. Furthermore, the insensitivity of chick short-term adaptation kinetics to temperature change is an argument against a role for neural refractoriness or receptor desensitization in adaptation (Crumling and Saunders 2005).…”
Section: Adaptation Across the Tonotopic Axis Of The Basilar Papillamentioning
confidence: 99%