Distortion product otoacoustic emission suppression tuning curves in normal-hearing and hearing-impaired human ears

Kopun

et al. 2011

Self Cite

Distortion-product otoacoustic emissions (DPOAEs) were used to describe suppression growth in normal-hearing humans. Data were collected at eight f 2 frequencies ranging from 0.5 to 8 kHz for L 2 levels ranging from 10 to 60 dB sensation level. For each f 2 and L 2 combination, suppression was measured for nine or eleven suppressor frequencies (f 3 ) whose levels varied from À20 to 85 dB sound pressure level (SPL). Suppression grew nearly linearly when f 3 % f 2 , grew more rapidly for f 3 < f 2 , and grew more slowly for f 3 > f 2 . These results are consistent with physiological and mechanical data from lower animals, as well as previous DPOAE data from humans, although no previous DPOAE study has described suppression growth for as wide a range of frequencies and levels. These trends were evident for all f 2 and L 2 combinations; however, some exceptions were noted. Specifically, suppression growth rate was less steep as a function of f 3 for f 2 frequencies 1 kHz. Thus, despite the qualitative similarities across frequency, there were quantitative differences related to f 2 , suggesting that there may be subtle differences in suppression for frequencies above 1 kHz compared to frequencies below 1 kHz.

Section: A Control Conditionssupporting

confidence: 82%

Section: A Control Conditionssupporting

confidence: 81%

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Growth of suppression in humans based on distortion-product otoacoustic emission measurements

Gorga

Kopun

et al. 2011

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“…6 might be consistent with the reduced differences between tip and tail thresholds as observed in frequency-threshold curves of auditory neurons (see, for example, Sewell, 1984), although we do not, as yet, have data that can be used to more directly test this hypothesis in humans. Tip-to-tail differences estimated from DPOAE suppression tuning curves have been interpreted as estimates of cochlear-amplifier gain (e.g., Pienkowski and Kunov, 2001;Mills, 1998;Gorga et al, 2002Gorga et al, ,2003. If the interpretation of the data shown in Figs.…”

Section: Slopes Of Dpoae I/o Functionsmentioning

confidence: 99%

Low-frequency and high-frequency cochlear nonlinearity in humans

Gorga

Dierking

et al. 2007

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Low-and high-frequency cochlear nonlinearity was studied by measuring DPOAE I/O functions at 0.5 and 4 kHz in 103 normal-hearing subjects. Behavioral thresholds at both f 2 's were used to set L 2 in dB SL for each subject. Primary levels were optimized by determining the L 1 resulting in the largest L dp for each L 2 for each subject and both f 2 's. DPOAE I/O functions were measured using L 2 inputs from −10 dB SL (0.5 kHz) or −20 dB SL (4 kHz) to 65 dB SL (both frequencies). Mean DPOAE I/O functions, averaged across subjects, differed between the two frequencies, even when threshold was taken into account. The slopes of the I/O functions were similar at 0.5 and 4 kHz for high-level inputs, with maximum compression ratios of about 4:1. At both frequencies, the maximum slope near DPOAE threshold was approximately 1, which occurred at lower levels at 4 kHz, compared to 0.5 kHz. These results suggest that there is a wider dynamic range and perhaps greater cochlearamplifier gain at 4 kHz, compared to 0.5 kHz. Caution is indicated, however, because of uncertainties in the interpretation of slope and because the confounding influence of differences in noise level could not be completely controlled.

“…Recent work has demonstrated that differences in distortion-product otoacoustic emission (DPOAE) suppression tuning curves (STCs) between ears with normal hearing (NH) and ears with hearing loss (HL) depend on the stimulus level at which comparisons are made (Abdala and Fitzgerald, 2003;Gorga et al, 2003;Gruhlke et al, 2012). When compared at equal stimulus-probe levels (primary levels for f 1 and f 2 , the stimulus frequencies eliciting the DPOAE) relative to threshold (i.e., sensation level, SL), STCs in ears with mild-to-moderate HL were characterized by reduced gain (as estimated by tip-to-tail differences) and broader tuning (based on the quality factor, Q), compared to ears with NH.…”

Section: Introductionmentioning

confidence: 99%

Tone-burst auditory brainstem response wave V latencies in normal-hearing and hearing-impaired ears

Lewis

Kopun

et al. 2015

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The metric used to equate stimulus level [sound pressure level (SPL) or sensation level (SL)] between ears with normal hearing (NH) and ears with hearing loss (HL) in comparisons of auditory function can influence interpretation of results. When stimulus level is equated in dB SL, higher SPLs are presented to ears with HL due to their reduced sensitivity. As a result, it may be difficult to determine if differences between ears with NH and ears with HL are due to cochlear pathology or level-dependent changes in cochlear mechanics. To the extent that level-dependent changes in cochlear mechanics contribute to auditory brainstem response latencies, comparisons between normal and pathologic ears may depend on the stimulus levels at which comparisons are made. To test this hypothesis, wave V latencies were measured in 16 NH ears and 15 ears with mild-to-moderate HL. When stimulus levels were equated in SL, latencies were shorter in HL ears. However, latencies were similar for NH and HL ears when stimulus levels were equated in SPL. These observations demonstrate that the effect of stimulus level on wave V latency is large relative to the effect of HL, at least in cases of mild-to-moderate HL.