Spectral modulation detection and vowel and consonant identifications in cochlear implant listeners

Saoji, Aniket A.; Litvak, Leonid M.; Spahr, Anthony J.; Eddins, David A.

doi:10.1121/1.3179670

Cited by 86 publications

(141 citation statements)

References 9 publications

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“…Basic psychoacoustic abilities have previously been shown to constrain hearing outcomes of CI users; for example, temporal modulation detection (Cazals et al 1994;Fu 2002;Won et al 2011;Gnansia et al 2014), spectral-ripple discrimination (Henry and Turner 2003;Henry et al 2005;Won et al 2007;Won et al 2010;Anderson et al 2011), spectral-ripple detection (Litvak et al 2007;Saoji et al 2009;Anderson et al 2012), Schroeder-phase discrimination (Drennan et al 2008), electrode discrimination (Henry et al 2000), and place-pitch discrimination (Donaldson and Nelson 2000). It should be noted that most of these previous studies have been conducted with postlingually deaf adults with CIs; thus, little is known about the development of psychoacoustic abilities in children with PLD who use CIs.…”

Section: Introductionmentioning

confidence: 99%

Acoustic Temporal Modulation Detection in Normal-Hearing and Cochlear Implanted Listeners: Effects of Hearing Mechanism and Development

Park

Won

Horn

et al. 2015

JARO

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Temporal modulation detection ability matures over many years after birth and may be particularly sensitive to experience during this period. Profound hearing loss during early childhood might result in greater perceptual deficits than a similar loss beginning in adulthood. We tested this idea by measuring performance in temporal modulation detection in profoundly deaf children and adults fitted with cochlear implants (CIs). At least two independent variables could constrain temporal modulation detection performance in children with CIs: altered encoding of modulation information due to the CIauditory nerve interface, and atypical development of central processing of sound information provided by CIs. The effect of altered encoding was investigated by testing subjects with one of two different hearing mechanisms (normal hearing vs. CI) and the effect of atypical development was studied by testing two different age groups. All subjects were tested for their ability to detect acoustic temporal modulations of sound amplitude. A comparison of the slope, or cutoff frequency, of the temporal modulation transfer functions (TMTFs) among the four subject groups revealed that temporal resolution was mainly constrained by hearing mechanism: normal-hearing listeners could detect smaller amplitude modulations at high modulation frequencies than CI users. In contrast, a comparison of the height of the TMTFs revealed a significant interaction between hearing mechanism and age group on overall sensitivity to temporal modulation: sensitivity was significantly poorer in children with CIs, relative to the other three groups. Results suggest that there is an agespecific vulnerability of intensity discrimination or non-sensory factors, which subsequently affects sensitivity to temporal modulation in prelingually deaf children who use CIs.

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Section: Introductionmentioning

confidence: 99%

Acoustic Temporal Modulation Detection in Normal-Hearing and Cochlear Implanted Listeners: Effects of Hearing Mechanism and Development

Park

Won

Horn

et al. 2015

JARO

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“…Over the past few years, spectral-ripple discrimination has been widely used in a variety of behavioral experiments with normal-hearing (NH), hearingimpaired (HI), and cochlear-implant (CI) listeners (e.g., Supin et al 1994;Henry et al 2000Henry et al , 2005Won et al 2007;Litvak et al 2007;Saoji et al 2009;Won et al 2010). For example, the ability of subjects to discriminate a reversal in the phase of the rippled shape (Henry et al 2000(Henry et al , 2005Won et al 2007), and the ability to differentiate between a spectral-ripple stimulus and white noise (Litvak et al 2007) have been evaluated.…”

Section: Introductionmentioning

confidence: 99%

Relationship Between Behavioral and Physiological Spectral-Ripple Discrimination

Won

Clinard

Kwon

et al. 2011

JARO

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Previous studies have found a significant correlation between spectral-ripple discrimination and speech and music perception in cochlear implant (CI) users. This relationship could be of use to clinicians and scientists who are interested in using spectral-ripple stimuli in the assessment and habilitation of CI users. However, previous psychoacoustic tasks used to assess spectral discrimination are not suitable for all populations, and it would be beneficial to develop methods that could be used to test all age ranges, including pediatric implant users. Additionally, it is important to understand how ripple stimuli are processed in the central auditory system and how their neural representation contributes to behavioral performance. For this reason, we developed a singleinterval, yes/no paradigm that could potentially be used both behaviorally and electrophysiologically to estimate spectral-ripple threshold. In experiment 1, behavioral thresholds obtained using the single-interval method were compared to thresholds obtained using a previously established three-alternative forcedchoice method. A significant correlation was found (r=0.84, p=0.0002) in 14 adult CI users. The spectralripple threshold obtained using the new method also correlated with speech perception in quiet and noise. In experiment 2, the effect of the number of vocoderprocessing channels on the behavioral and physiological threshold in normal-hearing listeners was determined. Behavioral thresholds, using the new singleinterval method, as well as cortical P1-N1-P2 responses changed as a function of the number of channels. Better behavioral and physiological performance (i.e., better discrimination ability at higher ripple densities) was observed as more channels added. In experiment 3, the relationship between behavioral and physiological data was examined. Amplitudes of the P1-N1-P2 "change" responses were significantly correlated with d′ values from the single-interval behavioral procedure. Results suggest that the single-interval procedure with spectral-ripple phase inversion in ongoing stimuli is a valid approach for measuring behavioral or physiological spectral resolution.

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“…When spectral ripple detection thresholds are measured individually at different spectral modulation rates, the resulting pattern of thresholds as a function of modulation rate is referred to as the spectral modulation transfer function (SMTF) (Saoji and Eddins, 2007;Saoji et al, 2009). Eddins and Bero (2007) measured the SMTF in normal-hearing listeners for rates between 0.25 and 10 ripples per octave (rpo), and found that the general form of the SMTF in that range is bandpass, with best modulation detection in the region between 2 and 4 rpo, and poorer detection at lower and higher modulation frequencies.…”

Section: Introductionmentioning

confidence: 99%

Assessing the role of spectral and intensity cues in spectral ripple detection and discrimination in cochlear-implant users

Anderson¹,

Oxenham

Nelson³

et al. 2012

The Journal of the Acoustical Society of America

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Measures of spectral ripple resolution have become widely used psychophysical tools for assessing spectral resolution in cochlear-implant (CI) listeners. The objective of this study was to compare spectral ripple discrimination and detection in the same group of CI listeners. Ripple detection thresholds were measured over a range of ripple frequencies and were compared to spectral ripple discrimination thresholds previously obtained from the same CI listeners. The data showed that performance on the two measures was correlated, but that individual subjects' thresholds (at a constant spectral modulation depth) for the two tasks were not equivalent. In addition, spectral ripple detection was often found to be possible at higher rates than expected based on the available spectral cues, making it likely that temporal-envelope cues played a role at higher ripple rates. Finally, spectral ripple detection thresholds were compared to previously obtained speech-perception measures. Results confirmed earlier reports of a robust relationship between detection of widely spaced ripples and measures of speech recognition. In contrast, intensity difference limens for broadband noise did not correlate with spectral ripple detection measures, suggesting a dissociation between the ability to detect small changes in intensity across frequency and across time.

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Spectral modulation detection and vowel and consonant identifications in cochlear implant listeners

Cited by 86 publications

References 9 publications

Acoustic Temporal Modulation Detection in Normal-Hearing and Cochlear Implanted Listeners: Effects of Hearing Mechanism and Development

Acoustic Temporal Modulation Detection in Normal-Hearing and Cochlear Implanted Listeners: Effects of Hearing Mechanism and Development

Relationship Between Behavioral and Physiological Spectral-Ripple Discrimination

Assessing the role of spectral and intensity cues in spectral ripple detection and discrimination in cochlear-implant users

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