The deterioration of hearing with age: Frequency selectivity, the critical ratio, the audiogram, and speech threshold

Patterson, Roy D.; Nimmo‐Smith, Ian; Weber, Daniel L.; Milroy, Robert

doi:10.1121/1.388652

Cited by 490 publications

(366 citation statements)

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“…Correlation analyses were performed to test whether k can be interpreted as truly representing differences in detection efficiency among listeners. These analyses were based on the assumptions that (1) efficiency is a central process (e.g., Patterson et al 1982; Werner and Bargones 1991) and (2) certain behavioral measurements should vary with k if such measurements are minimally influenced by peripheral nonlinearities. To test these assumptions, two behavioral measurements were evaluated: (1) temporal integration and (2) the "input SMR" for the off-frequency masker at 0-ms delay (i.e., a form of critical ratio; Hawkins and Stevens (1950)).…”

Section: Sensitivity To Kmentioning

confidence: 99%

“…Detection efficiency may explain superior performance in masking tasks for musicians than non-musicians (Fine and Moore 1993;Bidelman et al 2014), adults than children (Hill et al 2004), and in individuals without than with dyslexia or language impairments (Hartley and Moore 2002). Studies suggest that detection efficiency in normal-hearing listeners is primarily influenced by factors central to cochlear processing including memory, attention, and experience (Patterson et al 1982;Werner and Bargones 1991). Detection efficiency is a standard component of techniques used to estimate frequency selectivity from masking thresholds (Patterson and Nimmo-Smith 1980;Patterson et al 1982) and is often modeled as the degree to which probe power must exceed masker power (in dB) through an auditory filter at detection threshold (i.e., the signal-to-masker ratio or SMR).…”

Section: Introductionmentioning

confidence: 99%

“…Studies suggest that detection efficiency in normal-hearing listeners is primarily influenced by factors central to cochlear processing including memory, attention, and experience (Patterson et al 1982;Werner and Bargones 1991). Detection efficiency is a standard component of techniques used to estimate frequency selectivity from masking thresholds (Patterson and Nimmo-Smith 1980;Patterson et al 1982) and is often modeled as the degree to which probe power must exceed masker power (in dB) through an auditory filter at detection threshold (i.e., the signal-to-masker ratio or SMR). Detection efficien-cy can vary appreciably among normal-hearing listeners (Patterson 1976;Leek and Summers 1993) and accounts for individual differences in estimates of frequency resolution, suggesting that it may be a source of individual differences in TMCs.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Computational Modeling of Individual Differences in Behavioral Estimates of Cochlear Nonlinearities

Jennings

Ahlstrom

Dubno

2014

JARO

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Temporal masking curves (TMCs) are often used to estimate cochlear compression in individuals with normal and impaired hearing. These estimates may yield a wide range of individual differences, even among subjects with similar quiet thresholds. This study used an auditory model to assess potential sources of variance in TMCs from 51 listeners in Poling et al. [J Assoc Res Otolaryngol, 13:91-108 (2012)]. These sources included threshold elevation, the contribution of outer and inner hair cell dysfunction to threshold elevation, compression of the off-frequency linear reference, and detection efficiency. Simulations suggest that detection efficiency is a primary factor contributing to individual differences in TMCs measured in normal-hearing subjects, while threshold elevation and the contribution of outer and inner hair cell dysfunction are primary factors in hearing-impaired subjects. Approximating the most compressive growth rate of the cochlear response from TMCs was achieved only in subjects with the highest detection efficiency. Simulations included off-frequency nonlinearity in basilar membrane and inner hair cell processing; however, this nonlinearity did not improve predictions, suggesting that other sources, such as the decay of masking and the strength of the medial olivocochlear reflex, may mimic off-frequency nonlinearity. Findings from this study suggest that sources of individual differences can play a strong role in behavioral estimates of compression, and these sources should be considered when using forward masking to study cochlear function in individual listeners or across groups of listeners.

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Section: Sensitivity To Kmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Computational Modeling of Individual Differences in Behavioral Estimates of Cochlear Nonlinearities

Jennings

Ahlstrom

Dubno

2014

JARO

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“…Only six of the NH subjects participated in this experiment. The best-fitting rounded-exponential filter was estimated using the roex(p u , p l , r) filter model (Patterson et al, 1982;Glasberg and Moore, 1990). The average rms fitting error over all ears was 0.67 6 0.24 dB, indicating reasonable fits provided by the model.…”

Section: Frequency Selectivitymentioning

confidence: 99%

Relating binaural pitch perception to the individual listener’s auditory profile

Santurette¹,

Dau²

2012

The Journal of the Acoustical Society of America

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The ability of eight normal-hearing listeners and fourteen listeners with sensorineural hearing loss to detect and identify pitch contours was measured for binaural-pitch stimuli and salience-matched monaurally detectable pitches. In an effort to determine whether impaired binaural pitch perception was linked to a specific deficit, the auditory profiles of the individual listeners were characterized using measures of loudness perception, cognitive ability, binaural processing, temporal fine structure processing, and frequency selectivity, in addition to common audiometric measures. Two of the listeners were found not to perceive binaural pitch at all, despite a clear detection of monaural pitch. While both binaural and monaural pitches were detectable by all other listeners, identification scores were significantly lower for binaural than for monaural pitch. A total absence of binaural pitch sensation coexisted with a loss of a binaural signal-detection advantage in noise, without implying reduced cognitive function. Auditory filter bandwidths did not correlate with the difference in pitch identification scores between binaural and monaural pitches. However, subjects with impaired binaural pitch perception showed deficits in temporal fine structure processing. Whether the observed deficits stemmed from peripheral or central mechanisms could not be resolved here, but the present findings may be useful for hearing loss characterization.

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“…SS was manipulated by adding instrument endpoints in different proportions, ranging from 0.2 to 0.8 for each instrument and always summing to 1.0. Differences between mixtures were derived by calculating Euclidean distances between ERB-scaled spectra (Glasberg and Moore, 1990) that had been processed by a bank of auditory filters (Patterson et al, 1982). AD and SS series were then exhaustively adjusted across hundreds of participants until every pair of sounds separated by three stimulus steps (out of 18 steps total) was equally discriminable to every other pair within and across stimulus series ( 65% correct for changes along one dimension, 70% for changes along both dimensions; see Stilp et al, 2010 for details).…”

Section: Stimulimentioning

confidence: 99%

Non-isomorphism in efficient coding of complex sound properties

Stilp

Kluender

2011

The Journal of the Acoustical Society of America

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To the extent that sensorineural systems are efficient, stimulus redundancy should be captured in ways that optimize information transmission. Consistent with this principle, neural representations of sounds have been proposed to become “non-isomorphic,” increasingly abstract and decreasingly resembling the original (redundant) input. Here, non-isomorphism is tested in perceptual learning using AXB discrimination of novel sounds with two highly correlated complex acoustic properties and a randomly varying third dimension. Discrimination of sounds obeying the correlation became superior to that of sounds violating it despite widely varying physical acoustic properties, suggesting non-isomorphic representation of stimulus redundancy.

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The deterioration of hearing with age: Frequency selectivity, the critical ratio, the audiogram, and speech threshold

Cited by 490 publications

References 0 publications

Computational Modeling of Individual Differences in Behavioral Estimates of Cochlear Nonlinearities

Computational Modeling of Individual Differences in Behavioral Estimates of Cochlear Nonlinearities

Relating binaural pitch perception to the individual listener’s auditory profile

Non-isomorphism in efficient coding of complex sound properties

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