A Hearing-Model-Based Active-Learning Test for the Determination of Dead Regions

This article describes a Bayesian active-learning procedure for estimating the edge frequency, fe, of a dead region, that is, a region in the cochlea with no or very few functioning inner hair cells or neurons. The method is based on the psychophysical tuning curve (PTC) but estimates the shape of t...

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Bibliographic Details
Published inTrends in hearing Vol. 22; p. 2331216518788215
Main Authors Schlittenlacher, Josef, Turner, Richard E., Moore, Brian C. J.
Format Journal Article
LanguageEnglish
Published Los Angeles, CA SAGE Publications 01.01.2018
Sage Publications Ltd
SAGE Publishing
Subjects
Aged
Aged, 80 and over
Audiometry
Auditory Threshold
Bayes Theorem
Cochlea - innervation
Cochlea - physiology
Estimates
Female
Hair Cells, Auditory
Hearing - physiology
Hearing Tests
Humans
Male
Middle Aged
Original
Perceptual Masking
Reproducibility of Results
Time Factors
Bayesian active learning
dead region
hearing model
hearing test
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Summary:This article describes a Bayesian active-learning procedure for estimating the edge frequency, fe, of a dead region, that is, a region in the cochlea with no or very few functioning inner hair cells or neurons. The method is based on the psychophysical tuning curve (PTC) but estimates the shape of the PTC from the parameters of a hearing model, namely fe, and degree of outer hair cell loss. It chooses the masker frequency and level for each trial to be highly informative about the model parameters in the context of previous data. The procedure was tested using 14 ears from eight subjects previously diagnosed with high-frequency dead regions. The estimates of fe agreed well with estimates obtained using “Fast PTCs” or more extensive measurements from an earlier study. On average, 33 trials were needed for the estimate of fe to fall and stay within 0.3 Cams of the final “true” value on the equivalent rectangular bandwidth-number scale. The time needed to obtain a reliable estimate was 5 to 8 min. This is comparable to the time required for Fast PTCs and short enough to be used when fitting a hearing aid. Compared with Fast PTCs, the new method has the advantage of using yes-no judgments rather than continuous Békésy tracking. This allows the slope of a subject’s psychometric function and thus the reliability of his or her responses to be estimated, which in turn allows the test duration to be adjusted so as to achieve a given accuracy.
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ISSN:2331-2165
2331-2165
DOI:10.1177/2331216518788215