Graeme Clark Collection
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ItemMusical pitch perception by a user of the Nucleus 22-electrode cochlear implant [Abstract]( 1995)The study of how musical sounds are perceived by users of cochlear implants is both interesting and rewarding. In particular, it has the potential to provide detailed information on the perception of pitch with electrical stimulation of the auditory nerve. However, it is difficult to find subjects whose understanding of musical terminology and memory of conventional musical pitch relationships are adequate for this research. In our Melbourne laboratory, we have been fortunate to locate one implant user who received several years' formal training in the tuning of musical instruments before he lost his hearing. This subject is capable of estimating musical intervals in an open-set context, and can also adjust the interval between two "notes" to match a given target. Experiments involving both estimation and production of musical intervals have been carried out. Several parameters of the electrical stimulation have been varied to create notes of different pitches. These include the rate of steady pulse trains delivered to a fixed electrode position; the place of stimulation with a constant pulse rate; selected combinations of rate and place; and the frequency of sinusoidally amplitude-modulated (SAM) pulse trains delivered to a fixed electrode position. The results show that when pulse rate is the variable parameter, the rate ratio for a given musical interval closely approximates that for acoustic signals, provided that the electrode used is in the apical region of the cochlea. When the stimulation is moved to more-basal positions, the rate ratios become larger than the corresponding acoustic frequency ratios. Changing the place of stimulation with a constant pulse rate causes pitch changes that are comparable with the presumed place-to-characteristic frequency mapping of the subject's electrode array. Combinations of place and rate variation result in more complex effects, in which the pitch associated with the place of stimulation generally dominates, but is affected by the rate. The pitch of SAM pulse trains, although probably weaker than that of unmodulated low-rate pulse trains, is related to the modulation frequency. The ratio of modulation frequencies required for a given musical interval is larger than the corresponding ratio of acoustic frequencies in normal hearing.
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ItemDistribution of electrically stimulated nerve fibres in the cat cochlea( 1982)An implant electrode array for a cochlear hearing prosthesis has been developed with mechanical properties which allow atraumatic implantation into the human scala tympani. It consists of small platinum electrode bands welded around a flexible silicon rubber tube (Clark et al, 1979). The present study examines the properites of this electrode in electrically simulating the auidtory nerve. The electrode was inserted through the round window for a distance of 5-6mm into the scala tympani of the cat. Brainstem evoked responses and those from the round window were recorded when stimulating with square biphasic current pulses (0.1 msec/phase). Since there was usually less than 10-20 dB hearing loss in the implanted ear, it was possible to selectively mask components of these responses with high-pass filtered noise. The noise masked the response component arising from fibres in the cochlear region corresponding to the noise band. Responses were recorded in the presence of noise with different cut-off frequencies F1, F2 therefore yielded a response band-limited to the region f1-2. In this way it was possible to measure the amount of electrically stimulated activity in a number of different frequency bands. This technique is identical to that of derived response audiometry using acoustic stimulation. The input-output characteristics of the cochlea to a variety of acoustic transients were measured to exclude the possibility of either electrophonic hearing or altered basilar membrane characteristics contaminating the results. The figure shows the distributions of excited fibres using an electrode with an extended ground system running longitudinally in the cochlea. They were measure as the amplitude of the band-limited responses. Results were similar for bipolar electrodes and these electrodes are thus equally suitable for our present cochlear implant prosthesis.