AI Article Synopsis
- Multi-channel cochlear implants often misplace spectral information in the auditory nerve due to limited electrode insertion depth, leading to substantial immediate performance loss in listeners.
- In simulations, normal listeners showed high performance with unshifted spectral information (64% correct word identification), but significantly poorer performance with a simulated 6.5-mm spectral shift (only 1% correct).
- After nine short sessions of practice with the shifted simulations, listeners demonstrated notable improvements in identifying sounds and following speech, suggesting that short-term experiments may overstate the impact of these spectral shifts on performance.
Article Abstract
Multi-channel cochlear implants typically present spectral information to the wrong "place" in the auditory nerve array, because electrodes can only be inserted partway into the cochlea. Although such spectral shifts are known to cause large immediate decrements in performance in simulations, the extent to which listeners can adapt to such shifts has yet to be investigated. Here, the effects of a four-channel implant in normal listeners have been simulated, and performance tested with unshifted spectral information and with the equivalent of a 6.5-mm basalward shift on the basilar membrane (1.3-2.9 octaves, depending on frequency). As expected, the unshifted simulation led to relatively high levels of mean performance (e.g., 64% of words in sentences correctly identified) whereas the shifted simulation led to very poor results (e.g., 1% of words). However, after just nine 20-min sessions of connected discourse tracking with the shifted simulation, performance improved significantly for the identification of intervocalic consonants, medial vowels in monosyllables, and words in sentences (30% of words). Also, listeners were able to track connected discourse of shifted signals without lipreading at rates up to 40 words per minute. Although we do not know if complete adaptation to the shifted signals is possible, it is clear that short-term experiments seriously exaggerate the long-term consequences of such spectral shifts.
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| http://dx.doi.org/10.1121/1.428215 | DOI Listing |
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