Your search keyword '"Loudness Perception physiology"' showing total 1,205 results

151. Loudness adaptation accompanying ribbon synapse and auditory nerve disorders.

Author

Wynne DP, Zeng FG, Bhatt S, Michalewski HJ, Dimitrijevic A, and Starr A

Subjects

Adolescent, Adult, Aged, Auditory Perception physiology, Child, Cochlear Nerve physiology, Female, Hearing Disorders diagnosis, Hearing Disorders physiopathology, Humans, Hyperacusis diagnosis, Loudness Perception physiology, Male, Middle Aged, Young Adult, Acoustic Stimulation methods, Adaptation, Physiological physiology, Cochlear Nerve pathology, Hair Cells, Auditory, Inner physiology, Hyperacusis physiopathology

Abstract

Abnormal auditory adaptation is a standard clinical tool for diagnosing auditory nerve disorders due to acoustic neuromas. In the present study we investigated auditory adaptation in auditory neuropathy owing to disordered function of inner hair cell ribbon synapses (temperature-sensitive auditory neuropathy) or auditory nerve fibres. Subjects were tested when afebrile for (i) psychophysical loudness adaptation to comfortably-loud sustained tones; and (ii) physiological adaptation of auditory brainstem responses to clicks as a function of their position in brief 20-click stimulus trains (#1, 2, 3 … 20). Results were compared with normal hearing listeners and other forms of hearing impairment. Subjects with ribbon synapse disorder had abnormally increased magnitude of loudness adaptation to both low (250 Hz) and high (8000 Hz) frequency tones. Subjects with auditory nerve disorders had normal loudness adaptation to low frequency tones; all but one had abnormal adaptation to high frequency tones. Adaptation was both more rapid and of greater magnitude in ribbon synapse than in auditory nerve disorders. Auditory brainstem response measures of adaptation in ribbon synapse disorder showed Wave V to the first click in the train to be abnormal both in latency and amplitude, and these abnormalities increased in magnitude or Wave V was absent to subsequent clicks. In contrast, auditory brainstem responses in four of the five subjects with neural disorders were absent to every click in the train. The fifth subject had normal latency and abnormally reduced amplitude of Wave V to the first click and abnormal or absent responses to subsequent clicks. Thus, dysfunction of both synaptic transmission and auditory neural function can be associated with abnormal loudness adaptation and the magnitude of the adaptation is significantly greater with ribbon synapse than neural disorders.

Published

2013

152. Current steering with partial tripolar stimulation mode in cochlear implants.

Author

Wu CC and Luo X

Subjects

Adult, Aged, 80 and over, Computer Simulation, Deafness physiopathology, Electrodes, Female, Humans, Loudness Perception physiology, Middle Aged, Pitch Discrimination physiology, Cochlear Implantation methods, Cochlear Implants, Deafness therapy, Electric Stimulation Therapy methods

Abstract

The large spread of excitation is a major cause of poor spectral resolution for cochlear implant (CI) users. Partial tripolar (pTP) mode has been proposed to reduce current spread by returning an equally distributed fraction (0.5 × σ) of current to two flanking electrodes and the rest to an extra-cochlear ground. This study tested the efficacy of incorporating current steering into pTP mode to add spectral channels. Different proportions of current [α × σ and (1 - α) × σ] were returned to the basal and apical flanking electrodes respectively to shape the electric field. Loudness and pitch perception with α from 0 to 1 in steps of 0.1 was simulated with a computational model of CI stimulation and tested on the apical, middle, and basal electrodes of six CI subjects. The highest σ allowing for full loudness growth within the implant compliance limit was chosen for each main electrode. Pitch ranking was measured between pairs of loudness-balanced steered pTP stimuli with an α interval of 0.1 at the most comfortable level. Results demonstrated that steered pTP stimuli with α around 0.5 required more current to achieve equal loudness than those with α around 0 or 1, maybe due to more focused excitation patterns. Subjects usually perceived decreasing pitches as α increased from 0 to 1, somewhat consistent with the apical shift of the center of gravity of excitation pattern in the model. Pitch discrimination was not better with α around 0.5 than with α around 0 or 1, except for some subjects and electrodes. For three subjects with better pitch discrimination, about half of the pitch ranges of two adjacent main electrodes overlapped with each other in steered pTP mode. These results suggest that current steering with focused pTP mode may improve spectral resolution and pitch perception with CIs.

Published

2013

153. Audiovisual speech perception in children with developmental language disorder in degraded listening conditions.

Author

Meronen A, Tiippana K, Westerholm J, and Ahonen T

Subjects

Acoustic Stimulation methods, Child, Female, Humans, Language Tests, Lipreading, Loudness Perception physiology, Male, Noise, Phonetics, Photic Stimulation methods, Signal-To-Noise Ratio, Child Language, Language Development Disorders physiopathology, Speech Discrimination Tests, Speech Perception physiology

Abstract

Purpose: The effect of the signal-to-noise ratio (SNR) on the perception of audiovisual speech in children with and without developmental language disorder (DLD) was investigated by varying the noise level and the sound intensity of acoustic speech. The main hypotheses were that the McGurk effect (in which incongruent visual speech alters the auditory speech percept) would be weaker for children with DLD than for controls and that it would get stronger with decreasing SNR in both groups., Method: The participants were 8-year-old children with DLD and a sample of children with normal language development. In the McGurk stimuli, the consonant uttered by the voice differed from that articulated by the face. Three sound intensities (24, 36, and 48 dB) and noise levels (-12, 0, and +6 dB) were used. Perception of unisensory visual speech was also measured., Results: The children with DLD experienced a weak McGurk effect, that is, a weak influence of visual speech on audiovisual speech perception, which remained rather constant across SNR levels. The children with DLD were inaccurate at lipreading., Conclusions: Children with DLD have problems in perceiving spoken consonants presented audiovisually and visually. The weaker McGurk effect could be accounted for by the poorer lipreading ability of children with DLD.

Published

2013

154. Auditory imagery modulates frequency-specific areas in the human auditory cortex.

Author

Oh J, Kwon JH, Yang PS, and Jeong J

Subjects

Adult, Association Learning physiology, Brain Mapping methods, Female, Humans, Imagination physiology, Magnetic Resonance Imaging, Male, Neuronal Plasticity physiology, Visual Perception physiology, Young Adult, Acoustic Stimulation methods, Auditory Cortex physiology, Loudness Perception physiology, Music, Pitch Perception physiology

Abstract

Neural responses in early sensory areas are influenced by top-down processing. In the visual system, early visual areas have been shown to actively participate in top-down processing based on their topographical properties. Although it has been suggested that the auditory cortex is involved in top-down control, functional evidence of topographic modulation is still lacking. Here, we show that mental auditory imagery for familiar melodies induces significant activation in the frequency-responsive areas of the primary auditory cortex (PAC). This activation is related to the characteristics of the imagery: when subjects were asked to imagine high-frequency melodies, we observed increased activation in the high- versus low-frequency response area; when the subjects were asked to imagine low-frequency melodies, the opposite was observed. Furthermore, we found that A1 is more closely related to the observed frequency-related modulation than R in tonotopic subfields of the PAC. Our findings suggest that top-down processing in the auditory cortex relies on a mechanism similar to that used in the perception of external auditory stimuli, which is comparable to early visual systems.

Published

2013

155. On the necessity of full length electrical cochlear stimulation to suppress severe tinnitus in single-sided deafness.

Author

Punte AK, De Ridder D, and Van de Heyning P

Subjects

Electric Stimulation Therapy instrumentation, Female, Hearing Loss, Sensorineural complications, Hearing Loss, Sensorineural physiopathology, Hearing Loss, Sensorineural surgery, Hearing Loss, Unilateral physiopathology, Humans, Loudness Perception physiology, Male, Prospective Studies, Psychoacoustics, Quality of Life, Scala Tympani physiopathology, Scala Tympani surgery, Surveys and Questionnaires, Tinnitus physiopathology, Tinnitus surgery, Treatment Outcome, Cochlear Implants, Electric Stimulation Therapy methods, Hearing Loss, Unilateral complications, Hearing Loss, Unilateral surgery, Tinnitus etiology, Tinnitus therapy

Abstract

Background: Cochlear implantation (CI) has proven in long term prospective trials to reduce significantly incapacitating tinnitus in single sided deafness (SSD). Discussion arises whether electrical stimulation near the round window (RW) is also able to reduce tinnitus., Aim: to assess whether electrical stimulation of the basal first 4 intracochlear electrodes of a CI could sufficiently reduce tinnitus and to compare these results with stimulation with all CI electrodes., Material and Methods: 7 patients who met the criteria of severe tinnitus due to SSD were implanted with a Med-El Sonata Ti100 with a FlexSoftTM or Flex24TM electrode. After 4 weeks only the basal electrode pair (E12) nearest to the RW was activated. Each week the following pair was activated until the 4th pair.Thereafter all electrodes were activated. Tinnitus was assessed before CI surgery and before each electrode pair was activated. When all electrodes were fitted, evaluation was done after 1, 3 and 6 months.Tinnitus was assessed with Visual Analogue Scale (VAS) for loudness, psychoacoustic tinnitus loudness comparison at 1 kHz and Tinnitus Questionnaire (TQ) for the effect on quality of life. To evaluate the natural evolution, a tightly matched control group with severe tinnitus due to SSD was followed prospectively., Results: All the tinnitus outcome measures remained unchanged with 1, 2, 3 or 4 activated electrode pairs. With complete CI activation, the tinnitus decreased significantly comparable with earlier reports.Pre-implantation the tinnitus loudness was 8.2/10 on the VAS and was reduced to 4.1/10 6 months postimplantation.Psychometrically the loudness level went from 21.7 dB SL (SD: 16.02) to 7.5 dB SL (SD: 5.24)and the TQ from 60/84 to 39/84. The non-implanted group had no decrease of the tinnitus, the average VAS remained stable at 8.9/10 throughout the follow-up period of 6 months., Conclusion: with the current stimulation parameters electrical stimulation in the first 8e10 mm of the basal part of the scala tympani is insufficient to reduce tinnitus. However, stimulation over the complete CI length yields immediate tinnitus reduction confirming earlier results.

Published

2013

156. Illusory auditory continuity despite neural evidence to the contrary.

Author

Riecke L, Micheyl C, and Oxenham AJ

Subjects

Acoustic Stimulation methods, Adult, Auditory Threshold physiology, Female, Humans, Loudness Perception physiology, Male, Perceptual Masking physiology, Time Perception physiology, Young Adult, Auditory Perception physiology, Illusions physiology, Pattern Recognition, Physiological physiology, Psychoacoustics

Abstract

Many previous studies have shown that a tone that is momentarily -interrupted can be perceived as continuous if the interruption is completely masked by noise. It has been suggested this "continuity illusion" occurs only when peripheral neural responses contain no evidence that the signal was interrupted. In this study, we used a combination of psychophysical measures and computational simulations of peripheral auditory responses to examine whether the continuity illusion can be experienced under conditions where peripheral neural responses contain evidence that the signal did not continue through the masker. Our results provide an example of a salient continuity illusion despite evidence of an interruption in the peripheral representation, indicating that the illusion may depend more on global features of the interrupting sound, such as its long-term specific loudness, than on its fine-grained temporal structure.

Published

2013

157. The effect of presentation level on normal-hearing and hearing-impaired listeners' acceptable speech and noise levels.

Author

Recker KL and Edwards BW

Subjects

Acoustic Stimulation methods, Adult, Aged, Auditory Threshold physiology, Female, Humans, Loudness Perception physiology, Male, Middle Aged, Young Adult, Hearing physiology, Hearing Aids psychology, Hearing Loss, Sensorineural physiopathology, Hearing Loss, Sensorineural psychology, Hearing Loss, Sensorineural rehabilitation, Noise adverse effects, Patient Acceptance of Health Care psychology, Speech Perception physiology

Abstract

Background: Acceptable noise level (ANL) is a measure of the maximum amount of background noise that a listener is willing to "put up with" while listening to running speech. This test is unique in that it can predict with a high degree of accuracy who will be a successful hearing-aid wearer. Individuals who tolerate high levels of background noise are generally successful hearing-aid wearers, whereas individuals who do not tolerate background noise well are generally unsuccessful hearing-aid wearers., Purpose: Various studies have been unsuccessful in trying to relate ANLs to listener characteristics or other test results. Presumably, understanding the perceptual mechanism by which listeners determine their ANLs could provide an understanding of the ANL's unique predictive abilities and our current inability to correlate these results with other listener attributes or test results. As a first step in investigating this problem, the relationships between ANLs and other threshold measures where listeners adjust the signal-to-noise ratio (SNR) according to some criterion in a way similar to the ANL measure were examined. RESEARCH DESIGN AND STUDY SAMPLE: Ten normal-hearing and 10 hearing-impaired individuals participated in a laboratory experiment that followed a within-subjects, repeated-measures design., Data Collection and Analysis: Participants were seated in a sound booth. Running speech and noise (eight-talker babble) were presented from a loudspeaker at 0°, 3 ft in front of the participant. Individuals adjusted either the level of the speech or the level of the background noise. Specifically, with the speech fixed at different levels (50, 63, 75, or 88 dBA), participants performed the ANL task, in which they adjusted the level of the background noise to the maximum level at which they were willing to listen while following the speech. With the noise fixed at different levels (50, 60, 70, or 80 dBA), participants adjusted the level of the speech to the minimum, preferred, or maximum levels at which they were willing to listen while following the speech. Additionally, for the minimum acceptable speech level task, each participant was tested at four participant-specific noise levels, based on his/her ANL results. To emphasize that the speech level was adjusted in these measurements, three new terms were coined: "minimum acceptable speech level" (MinASL), "preferred speech level" (PSL), and "maximum acceptable speech level" (MaxASL). Each condition was presented twice, and the results were averaged. Test order and presentation level were randomized. Hearing-impaired participants were tested in the aided condition only., Results: For most participants, as the presentation level increased, SNRs increased for the ANL test but decreased for the MinASL, PSL, and MaxASL tests. For a few participants, ANLs were similar to MinASLs. For most test conditions, the normal-hearing results were not significantly different from those of the hearing-impaired participants., Conclusions: For most participants, stimulus level affected the SNRs at which they were willing to listen. However, a subset of listeners was willing to listen at a constant SNR for the ANL and MinASL tests. Furthermore, for these individuals, ANLs and MinASLs were roughly equal, suggesting that these individuals may have used the same perceptual criterion for both tests., (American Academy of Audiology.)

Published

2013

158. Detection thresholds for amplitude modulations of tones in budgerigar, rabbit, and human.

Author

Carney LH, Ketterer AD, Abrams KS, Schwarz DM, and Idrobo F

Subjects

Animals, Conditioning, Psychological physiology, Cues, Humans, Loudness Perception physiology, Noise, Perceptual Masking physiology, Pitch Perception physiology, Psychoacoustics, Rabbits, Species Specificity, Time Perception physiology, Auditory Threshold physiology, Melopsittacus physiology, Models, Animal

Abstract

Envelope fluctuations of complex sounds carry information that is -essential for many types of discrimination and for detection in noise. To study the neural representation of envelope information and mechanisms for processing of this temporal aspect of sounds, it is useful to identify an animal model that can -sensitively detect amplitude modulations (AM). Low modulation frequencies, which dominate speech sounds, are of particular interest. Yet, most animal -models studied previously are relatively insensitive to AM at low modulation -frequencies. Rabbits have high thresholds for low-frequency modulations, -especially for tone carriers. Rhesus macaques are less sensitive than humans to low-frequency -modulations of wideband noise (O'Conner et al. Hear Res 277, 37-43, 2011). Rats and -chinchilla also have higher thresholds than humans for amplitude -modulations of noise (Kelly et al. J Comp Psychol 120, 98-105, 2006; Henderson et al. J Acoust Soc Am 75, -1177-1183, 1984). In contrast, the budgerigar has thresholds for AM detection of wideband noise similar to those of human listeners at low -modulation frequencies (Dooling and Searcy. Percept Psychophys 46, 65-71, 1981). A -one-interval, two-alternative operant conditioning procedure was used to estimate AM -detection thresholds for 4-kHz tone carriers at low modulation -frequencies (4-256 Hz). Budgerigar thresholds are comparable to those of human subjects in a comparable task. Implications of these comparative results for temporal coding of complex sounds are discussed. Comparative results for masked AM detection are also presented.

Published

2013

159. A new approach to sound source segregation.

Author

Lutfi RA, Liu CJ, and Stoelinga CN

Subjects

Hearing Aids, Hearing Loss physiopathology, Hearing Loss therapy, Humans, Noise, Phonetics, Signal Detection, Psychological physiology, Loudness Perception physiology, Models, Neurological, Psychoacoustics, Psychophysics methods, Speech Perception physiology

Abstract

We rely critically on our ability to 'hear out' (segregate) individual sound sources in a mixture. Yet, despite its importance, little is known regarding this -ability. Perturbation analysis is a psychophysical method that has been successfully applied to related problems in vision [Murray, R.F. 2011. J. of Vision 11, 1-25]. Here the approach is adapted to audition. The application proceeds in three stages: First, simple speech and environmental sounds are synthesized according to a generative model of the sound--producing source. Second, listener decision strategy in segregating target from non--target (noise) sources is determined from decision weights (regression coefficients) relating listener judgments regarding the target to lawful perturbations in acoustic parameters, as dictated by the generative model. Third, factors limiting segregation are identified by comparing the obtained weights and residuals to those of a maximum-likelihood (ML) observer that optimizes segregation based on the equations of motion of the generating source. Here, the approach is applied to test between the two major models of sound source segregation; target enhancement versus noise cancellation. The results indicate a tendency of noise segregation to preempt target enhancement when the noise source is unchanging. However, the results also show individual differences in segregation strategy that are not evident in the measures of performance accuracy alone.

Published

2013

160. Psychoacoustic tinnitus loudness and tinnitus-related distress show different associations with oscillatory brain activity.

Author

Balkenhol T, Wallhäusser-Franke E, and Delb W

Subjects

Adult, Aged, Analysis of Variance, Auditory Perception physiology, Electroencephalography, Hearing Loss complications, Humans, Magnetoencephalography, Male, Middle Aged, Perceptual Masking physiology, Psychoacoustics, Tinnitus complications, Brain physiopathology, Hearing Loss physiopathology, Loudness Perception physiology, Tinnitus physiopathology

Abstract

Background: The phantom auditory perception of subjective tinnitus is associated with aberrant brain activity as evidenced by magneto- and electroencephalographic studies. We tested the hypotheses (1) that psychoacoustically measured tinnitus loudness is related to gamma oscillatory band power, and (2) that tinnitus loudness and tinnitus-related distress are related to distinct brain activity patterns as suggested by the distinction between loudness and distress experienced by tinnitus patients. Furthermore, we explored (3) how hearing impairment, minimum masking level, and (4) psychological comorbidities are related to spontaneous oscillatory brain activity in tinnitus patients., Methods and Findings: Resting state oscillatory brain activity recorded electroencephalographically from 46 male tinnitus patients showed a positive correlation between gamma band oscillations and psychoacoustic tinnitus loudness determined with the reconstructed tinnitus sound, but not with the other psychoacoustic loudness measures that were used. Tinnitus-related distress did also correlate with delta band activity, but at electrode positions different from those associated with tinnitus loudness. Furthermore, highly distressed tinnitus patients exhibited a higher level of theta band activity. Moreover, mean hearing loss between 0.125 kHz and 16 kHz was associated with a decrease in gamma activity, whereas minimum masking levels correlated positively with delta band power. In contrast, psychological comorbidities did not express significant correlations with oscillatory brain activity., Conclusion: Different clinically relevant tinnitus characteristics show distinctive associations with spontaneous brain oscillatory power. Results support hypothesis (1), but exclusively for the tinnitus loudness derived from matching to the reconstructed tinnitus sound. This suggests to preferably use the reconstructed tinnitus spectrum to determine psychoacoustic tinnitus loudness. Results also support hypothesis (2). Moreover, hearing loss and minimum masking level correlate with oscillatory power in distinctive frequency bands. The lack of an association between psychological comorbidities and oscillatory power may be attributed to the overall low level of mental health problems in the present sample.

Published

2013

161. Cochlear compression: recent insights from behavioural experiments.

Author

Plack CJ

Subjects

Animals, Auditory Threshold physiology, Behavior, Humans, Mammals, Perceptual Masking physiology, Pitch Perception physiology, Basilar Membrane physiology, Cochlea physiology, Hearing physiology, Loudness Perception physiology, Models, Biological

Abstract

Although physiological measures have provided a great deal of -information about the basilar membrane (BM) response of non-human mammals, it is only relatively recently that behavioural techniques have allowed researchers to measure accurately the non-linear characteristics of the human BM. These techniques are based on forward masking, in which the threshold for detecting a signal is measured in the presence of a prior masking sound. Two popular techniques, the growth of forward masking technique and the temporal masking curve technique, rely on the fact that compression in the base of the cochlea is largely restricted to frequencies close to the characteristic frequency (CF) of each place. By comparing the response to a masker with a frequency equal to that of the signal with the response to a lower-frequency masker, it is possible to infer the CF response. These measures have shown that BM compression in humans matches that of other mammals and that compression is absent in listeners with moderate-to-severe cochlear hearing loss, probably reflecting outer hair cell dysfunction. Another technique, the additivity of forward masking (AFM) technique, does not rely on a comparison between on- and off-frequency maskers, but instead measures the effect on threshold of combining two nonoverlapping maskers, an effect which is magnified by compression. The difference between thresholds in the single- and combined-masker conditions can be used to estimate compression. The AFM technique has provided evidence that strong compression extends down to low CFs in humans, a finding inconsistent with direct measures of the BM response in other mammals. Furthermore, recent AFM results suggest that there may be an additional source of compression central to the BM. This more central compression also appears to be affected by hearing loss and may reflect non-linear processes in the transduction mechanism of the inner hair cells.

Published

2013

162. An active loudness model suggesting tinnitus as increased central noise and hyperacusis as increased nonlinear gain.

Author

Zeng FG

Subjects

Animals, Auditory Threshold physiology, Biomedical Engineering, Hearing Loss etiology, Hearing Loss physiopathology, Humans, Noise, Nonlinear Dynamics, Systems Biology, Tinnitus therapy, Hyperacusis etiology, Hyperacusis physiopathology, Loudness Perception physiology, Models, Biological, Tinnitus etiology, Tinnitus physiopathology

Abstract

The present study uses a systems engineering approach to delineate the relationship between tinnitus and hyperacusis as a result of either hearing loss in the ear or an imbalanced state in the brain. Specifically examined is the input-output function, or loudness growth as a function of intensity in both normal and pathological conditions. Tinnitus reduces the output dynamic range by raising the floor, while hyperacusis reduces the input dynamic range by lowering the ceiling or sound tolerance level. Tinnitus does not necessarily steepen the loudness growth function but hyperacusis always does. An active loudness model that consists of an expansion stage following a compression stage can account for these key properties in tinnitus and hyperacusis loudness functions. The active loudness model suggests that tinnitus is a result of increased central noise, while hyperacusis is due to increased nonlinear gain. The active loudness model also generates specific predictions on loudness growth in tinnitus, hyperacusis, hearing loss or any combinations of the three conditions. These predictions need to be verified by experimental data and have explicit implications for treatment of tinnitus and hyperacusis., (Copyright © 2012 Elsevier B.V. All rights reserved.)

Published

2013

163. The dynamic range paradox: a central auditory model of intensity change detection.

Author

Simpson AJ and Reiss JD

Subjects

Computer Simulation, Humans, Adaptation, Physiological physiology, Hearing physiology, Loudness Perception physiology, Models, Biological, Sound

Abstract

In this paper we use empirical loudness modeling to explore a perceptual sub-category of the dynamic range problem of auditory neuroscience. Humans are able to reliably report perceived intensity (loudness), and discriminate fine intensity differences, over a very large dynamic range. It is usually assumed that loudness and intensity change detection operate upon the same neural signal, and that intensity change detection may be predicted from loudness data and vice versa. However, while loudness grows as intensity is increased, improvement in intensity discrimination performance does not follow the same trend and so dynamic range estimations of the underlying neural signal from loudness data contradict estimations based on intensity just-noticeable difference (JND) data. In order to account for this apparent paradox we draw on recent advances in auditory neuroscience. We test the hypothesis that a central model, featuring central adaptation to the mean loudness level and operating on the detection of maximum central-loudness rate of change, can account for the paradoxical data. We use numerical optimization to find adaptation parameters that fit data for continuous-pedestal intensity change detection over a wide dynamic range. The optimized model is tested on a selection of equivalent pseudo-continuous intensity change detection data. We also report a supplementary experiment which confirms the modeling assumption that the detection process may be modeled as rate-of-change. Data are obtained from a listening test (N = 10) using linearly ramped increment-decrement envelopes applied to pseudo-continuous noise with an overall level of 33 dB SPL. Increments with half-ramp durations between 5 and 50,000 ms are used. The intensity JND is shown to increase towards long duration ramps (p<10(-6)). From the modeling, the following central adaptation parameters are derived; central dynamic range of 0.215 sones, 95% central normalization, and a central loudness JND constant of 5.5×10(-5) sones per ms. Through our findings, we argue that loudness reflects peripheral neural coding, and the intensity JND reflects central neural coding.

Published

2013

164. Electrical stimulation and tinnitus: neuroplasticity, neuromodulation, neuroprotection.

Author

Abraham S, Barbara G, and Arnold S

Subjects

Adolescent, Adult, Aged, Audiometry, Evoked Response, Evoked Potentials, Auditory, Brain Stem physiology, Female, Humans, Loudness Perception physiology, Male, Middle Aged, Nerve Net physiopathology, Pitch Discrimination physiology, Young Adult, Electric Stimulation Therapy, Neural Inhibition physiology, Neuronal Plasticity physiology, Tinnitus physiopathology, Tinnitus therapy

Abstract

Neuroplasticity (NPL), neuromodulation (NM), and neuroprotection (NPT) are ongoing biophysiological processes that are linked together in sensory systems, the goal being the maintenance of a homeostasis of normal sensory function in the central nervous system. It is hypothesized that when the balance between excitatory - inhibitory action is broken in sensory systems, predominantly due to neuromodulatory activity with reduced induced inhibition and excitation predominates, sensory circuits become plastic with adaptation at synaptic levels to environmental inputs(1). Tinnitus an aberrant auditory sensation, for all clinical types, is clinically considered to reflect a failure of NPL, NM, and NPT to maintain normal auditory function at synaptic levels in sensory cortex and projected to downstream levels in the central auditory system in brain and sensorineural elements in ear. Clinically, the tinnitus sensation becomes behaviorally manifest with varying degrees of annoyance, reflecting a principle of sensory physiology that each sensation has components, i.e. sensory, affect/behavior, psychomotor and memory. Modalities of tinnitus therapies, eg instrumentation, pharmacology, surgery, target a particular component of tinnitus, with resultant activation of neuromodulators at multiple neuromodulatory centers in brain and ear. Effective neuromodulation at sensory neuronal synaptic levels results in NPL in sensory cortex, NPT and tinnitus relief. Functional brain imaging, metabolic (PET brain) and electrophysiology quantitative electroencephalography (QEEG) data in a cochlear implant soft failure patient demonstrates what is clinically considered to reflect NPL, NM, NPT. The reader is provided with a rationale for tinnitus diagnosis and treatment, with a focus on ES, reflecting the biology underlying NPL, NM, NPT.

Published

2013

165. Clinical characteristics associated with different strengths of loudness dependence of auditory evoked potentials (LDAEP) in major depressive disorder.

Author

Min JA, Lee SH, Lee SY, Chae JH, Lee CU, Park YM, and Bae SM

Subjects

Adolescent, Adult, Aged, Electroencephalography, Female, Humans, Male, Middle Aged, Severity of Illness Index, Suicide, Attempted, Acoustic Stimulation methods, Auditory Cortex physiology, Depressive Disorder, Major physiopathology, Evoked Potentials, Auditory physiology, Loudness Perception physiology

Abstract

Loudness dependence of auditory evoked potentials (LDAEP), also called as intensity dependence of auditory evoked potentials (IDAP), has been proposed as a potential marker for central serotonergic tone and has been noticed for its possible clinical implications in depression. However, its distributions in major depressive disorder (MDD) and factors affecting it are largely unknown. In this study, we examined its distribution and relationships with various demographic and clinical variables in MDD patients. In 143 MDD patients, the LDAEP was measured using five intensities of auditory stimulus. The influences of ten independent variables (age, gender, education years, marital status, psychiatric family history, age of onset, suicide attempt history, depression severity, later augmentation of mood stabilizer, and smoking status) on the LDAEP strength were examined using univariate analyses and data mining method. The mean (±S.D.) LDAEP was 0.90 (±0.73)μV/10dB (-0.78-3.83μV/10dB). Female gender, smoking, and being married were consistently associated with a weaker LDAEP. In the pathway model, sequential combination of being male, living alone, and older age predicted the strongest LDAEP, whereas female gender, older age, and smoking predicted the weakest LDAEP. These variables need to be considered when interpreting the LDAEP., (Copyright © 2012 Elsevier Ireland Ltd. All rights reserved.)

Published

2012

166. Vicarious action preparation does not result in sensory attenuation of auditory action effects.

Author

Weiss C and Schütz-Bosbach S

Subjects

Acoustic Stimulation, Adult, Anticipation, Psychological, Female, Humans, Male, Sound, Auditory Perception physiology, Loudness Perception physiology

Abstract

The perception of sensory effects generated by one's own actions is typically attenuated compared to the same effects generated externally. However, it is unclear whether this specifically relates to self-generation. Recent studies showed that sensory attenuation mainly relies on action preparation, not actual action execution. Hence, an attenuation of sensory effects generated by another person might occur if these actions can be anticipated and thus be prepared for. Here, we compared the perceived loudness of sounds generated by one's own actions and actions of another person that either could or could not be anticipated. We found an attenuation of the perceived loudness for self- as compared to other-generated sounds. This difference was independent of whether the sound-eliciting actions of the other person could be anticipated or not. Thus, sensory attenuation seems to be specifically tied to self-generation instead of being a secondary effect of agent-independent preparation for an upcoming action., (Copyright © 2012 Elsevier Inc. All rights reserved.)

Published

2012

167. Development of a loudness normalisation strategy for combined cochlear implant and acoustic stimulation.

Author

Francart T and McDermott HJ

Subjects

Acoustic Stimulation statistics & numerical data, Aged, Hearing Aids statistics & numerical data, Humans, Middle Aged, Models, Biological, Psychoacoustics, Signal Processing, Computer-Assisted, Sound Localization physiology, Acoustic Stimulation methods, Cochlear Implants, Loudness Perception physiology

Abstract

Users of a cochlear implant together with a hearing aid in the non-implanted ear currently use devices that were developed separately and are often fitted separately. This results in very different growth of loudness with level in the two ears, potentially leading to decreased wearing comfort and suboptimal perception of interaural level differences. A loudness equalisation strategy, named 'SCORE bimodal', is proposed. It equalises loudness growth for the two modalities using existing models of loudness for acoustic and electric stimulation, and is suitable for implementation in wearable devices. Loudness balancing experiments were performed with six bimodal listeners to validate the strategy. In a first set of experiments, the function of each loudness model used was validated by balancing the loudness of four harmonic complexes of different bandwidths, ranging from 200 Hz to 1000 Hz, separately for each ear. Both the electric and acoustic loudness models predicted the data well. In a second set of experiments, binaural balancing was done for the same stimuli. It was found that SCORE significantly improved binaural balance., (Copyright © 2012 Elsevier B.V. All rights reserved.)

Published

2012

168. Acceptable noise level and psychophysical masking.

Author

Rishiq DA, Harkrider AW, and Hedrick MS

Subjects

Acoustic Stimulation, Adult, Efferent Pathways physiology, Humans, Individuality, Young Adult, Auditory Pathways physiology, Auditory Threshold physiology, Loudness Perception physiology, Noise, Perceptual Masking physiology

Abstract

Purpose: Individuals with low acceptable noise levels (ANLs) accept more noise than individuals with high ANLs. To determine whether ANL is influenced more by afferent or efferent cortical responsiveness, the authors measured differences in temporal masking responses between individuals with low versus high ANLs. If listeners with low ANLs have masked thresholds similar to those of listeners with high ANLs, low ANLs may be due to reduced afferent responsiveness affecting both the masker and signal. If, however, listeners with low ANLs have masked thresholds better than that of listeners with high ANLs, there may be a physiological basis for improved selective attention via stronger efferent inhibition of the "unwanted" sound., Method: Participants were 19 listeners with normal hearing between the ages of 19 and 35. Ten listeners had low ANLs and 9 had high ANLs. All participants were compared using tone-in-noise simultaneous, forward, and backward masking tasks., Results: Results revealed no observed differences in masked thresholds between the low versus high ANL group. The low ANL group, however, required significantly more threshold runs to achieve criterion necessary for threshold determinations., Conclusions: Findings suggest that low ANLs are associated with reduced afferent cortical responsiveness and, possibly, decreased sustained attention.

Published

2012

169. Digital music exposure reliably induces temporary threshold shift in normal-hearing human subjects.

Author

Le Prell CG, Dell S, Hensley B, Hall JW 3rd, Campbell KC, Antonelli PJ, Green GE, Miller JM, and Guire K

Subjects

Acoustic Stimulation methods, Adolescent, Adult, Audiometry, Pure-Tone, Female, Humans, Loudness Perception physiology, Male, Otoacoustic Emissions, Spontaneous physiology, Prospective Studies, Sound Spectrography, Young Adult, Auditory Fatigue, MP3-Player, Music

Abstract

Objectives: One of the challenges for evaluating new otoprotective agents for potential benefit in human populations is the availability of an established clinical paradigm with real-world relevance. These studies were explicitly designed to develop a real-world digital music exposure that reliably induces temporary threshold shift (TTS) in normal-hearing human subjects., Design: Thirty-three subjects participated in studies that measured effects of digital music player use on hearing. Subjects selected either rock or pop music, which was then presented at 93 to 95 (n = 10), 98 to 100 (n = 11), or 100 to 102 (n = 12) dBA in-ear exposure level for a period of 4 hr. Audiograms and distortion product otoacoustic emissions (DPOAEs) were measured before and after music exposure. Postmusic tests were initiated 15 min, 1 hr 15 min, 2 hr 15 min, and 3 hr 15 min after the exposure ended. Additional tests were conducted the following day and 1 week later., Results: Changes in thresholds after the lowest-level exposure were difficult to distinguish from test-retest variability; however, TTS was reliably detected after higher levels of sound exposure. Changes in audiometric thresholds had a "notch" configuration, with the largest changes observed at 4 kHz (mean = 6.3 ± 3.9 dB; range = 0-14 dB). Recovery was largely complete within the first 4 hr postexposure, and all subjects showed complete recovery of both thresholds and DPOAE measures when tested 1 week postexposure., Conclusions: These data provide insight into the variability of TTS induced by music-player use in a healthy, normal-hearing, young adult population, with music playlist, level, and duration carefully controlled. These data confirm the likelihood of temporary changes in auditory function after digital music-player use. Such data are essential for the development of a human clinical trial protocol that provides a highly powered design for evaluating novel therapeutics in human clinical trials. Care must be taken to fully inform potential subjects in future TTS studies, including protective agent evaluations, that some noise exposures have resulted in neural degeneration in animal models, even when both audiometric thresholds and DPOAE levels returned to pre-exposure values.

Published

2012

170. Occipital cortical thickness predicts performance on pitch and musical tasks in blind individuals.

Author

Voss P and Zatorre RJ

Subjects

Adult, Age of Onset, Auditory Perception physiology, Discrimination, Psychological physiology, Female, Humans, Image Processing, Computer-Assisted, Loudness Perception physiology, Magnetic Resonance Imaging, Male, Middle Aged, Occipital Lobe anatomy & histology, Psychomotor Performance physiology, Regression Analysis, Visual Cortex pathology, Blindness pathology, Blindness psychology, Music psychology, Occipital Lobe pathology, Pitch Discrimination physiology

Abstract

The behavioral and neurofunctional consequences of blindness often include performance enhancements and recruitment of occipital regions for nonvisual tasks. How the neuroanatomical changes resulting from this sensory loss relate to these functional changes is, however, less clear. Previous studies using cortical thickness (CT) measures have shown thicker occipital cortex in early-blind (EB) individuals compared with sighted controls. We hypothesized that this finding reflects the crossmodal plasticity often observed in blind individuals and thus could reflect behavioral adaptations. To address this issue, CT measures in blind (early and late) and sighted subjects were obtained along with several auditory behavioral measures in an attempt to relate behavioral and neuroanatomical changes. Group contrasts confirmed previous results in showing thicker occipital cortex in the EB. Regression analyses between CT measures across the whole brain of all blind individuals with the behavioral scores from 2 tasks in which EB subjects were superior (pitch and melody discrimination) showed that CT of occipital areas was directly related to behavioral enhancements. These findings constitute a compelling demonstration that anatomical changes in occipital areas are directly related to heightened behavioral abilities in the blind and hence support the idea that these anatomical features reflect adaptive compensatory plasticity.

Published

2012

171. Auditory brainstem responses to level-specific chirps in normal-hearing adults.

Author

Kristensen SG and Elberling C

Subjects

Adult, Female, Humans, Loudness Perception physiology, Male, Models, Neurological, Reaction Time physiology, Reference Values, Young Adult, Acoustic Stimulation methods, Cochlea physiology, Evoked Potentials, Auditory, Brain Stem physiology, Hearing physiology

Abstract

Background: Upward chirps are often designed to compensate for the cochlear traveling wave delay which is regarded as independent of stimulation level. A chirp based on a traveling wave model is therefore referred to as a level-independent chirp. Another compensation strategy, for instance based on frequency-specific auditory brainstem response (ABR) latencies, results in a chirp that changes with stimulation level and is therefore referred to as a level-dependent chirp. One such strategy, the direct approach, results in a chirp family that is called the level-specific chirp. The level dependence is in agreement with the findings that the chirp, which generates the largest ABR in normal-hearing adults, has a duration (sweeping rate) that changes with stimulus level. A direct comparison of ABRs to a fixed chirp and to a level-specific chirp has not been performed at higher levels of stimulation where the differences are thought to have the greatest effect on the ABR characteristics from normal-hearing adults., Purpose: To make a direct comparison of the ABRs to two different chirp stimuli-a level-specific chirp (LS-Chirp) and a level-independent chirp (CE-Chirp)-and to evaluate the hypothesis that at higher levels of stimulation the LS-Chirp generates significantly higher response amplitudes, and produces higher resolution of the different peaks in the ABR than the CE-Chirp., Research Design: ABRs are recorded in 10 normal-hearing adults (20 ears) in response to three stimuli at four presentation levels using ER-3A insert earphones. The three stimuli are (1) a level-specific chirp (LS-Chirp), (2) a level-independent chirp (CE-Chirp), and (3) a standard 100-μs click as a reference. The recorded ABRs are evaluated by the peak to trough amplitude (wave V), the peak latency (wave V), the frequency of appearance of wave I, III, and V, and the Grand Average waveforms. Amplitude and latency differences are evaluated statistically by the Wilcoxon matched-pair signed rank test., Results: At higher levels (80 dB nHL), the amplitude and waveform resolution of the ABR to the LS-Chirp are significantly higher than to the CE-Chirp. At lower levels (20, 40, and 60 dB nHL), no significant differences are found between the amplitudes of the ABR to the two stimuli, but at 60 dB nHL the waveform resolution is better for the LS-Chirp than for the CE-Chirp. For all levels, the amplitude of the ABRs to the two chirps are significantly larger than to the Click, except at 80 dB nHL where the ABR to the CE-Chirp gets distorted and low in amplitude. The differences between the ABR latencies to the three stimuli are large at higher levels, but small at lower levels. At higher levels, the LS-Chirp and the Click generate similar resolutions of the main ABR peaks, but the ABRs to the LS-Chirp are significantly larger than to the Click., Conclusions: The study confirms the experimental hypothesis that at higher levels of stimulation the LS-Chirp generates significantly higher response amplitudes than both the CE-Chirp and the Click. It also generates a much better response resolution than the CE-Chirp, but the same response resolution as the Click., (American Academy of Audiology.)

Published

2012

172. Scalp- and sLORETA-derived loudness dependence of auditory evoked potentials (LDAEPs) in unmedicated depressed males and females and healthy controls.

Author

Jaworska N, Blier P, Fusee W, and Knott V

Subjects

Acoustic Stimulation, Adult, Analysis of Variance, Electroencephalography, Female, Humans, Male, Middle Aged, Psychiatric Status Rating Scales, Psychoacoustics, Reaction Time physiology, Statistics as Topic, Brain Mapping, Depression physiopathology, Evoked Potentials, Auditory physiology, Loudness Perception physiology, Sex Characteristics

Abstract

Objective: As major depressive disorder (MDD) is associated with altered 5-HT activity, we probed intensity-dependent auditory evoked potentials (AEPs) and loudness dependence of the AEP (LDAEP) slopes, shown pre-clinically to be inversely related to 5-HT activity, in MDD., Methods: AEPs and LDAEP slopes were measured in MDD (N=50; 27 females) and controls (N=43; 23 females). Correlations between scalp AEPs/LDAEPs and low-resolution electromagnetic tomography (sLORETA)-derived indices were assessed., Results: Smaller scalp intensity-dependent N1 and N1/P2 amplitudes in MDD versus control males and longer P2 latencies in MDD versus control females were found; no LDAEP group differences existed. Females had greater scalp AEPs, steeper N1 and N1/P2 scalp LDAEPs as well as greater intensity-dependent primary auditory cortex activation during the N1 than males. Scalp LDAEPs correlated weak-moderately with sLORETA counterparts. P2 LDAEP-sLORETA correlated negatively with MADRS scores. Female P2 and N1/P2 LDAEP-sLORETA correlated negatively with HAMD-17 and MADRS scores., Conclusions: MDD was not associated with altered LDAEPs. Impaired processing or potentiated inhibition of auditory stimuli was found in MDD males; longer processing existed in MDD females. Inverse relationships between LDAEPs and clinical scores may be related to treatment history, personality and/or MDD features., Significance: MDD was not associated with an altered LDAEP, though subtle AEPs alterations were noted in MDD., (Crown Copyright © 2012. Published by Elsevier Ireland Ltd. All rights reserved.)

Published

2012

173. Loudness dependence of auditory evoked potentials (LDAEP) in clinical monitoring of suicidal patients with major depression: a pilot study.

Author

Uhl I, Illes F, Graßnickel V, Echterhoff S, Norra C, and Juckel G

Subjects

Adult, Depressive Disorder, Major metabolism, Depressive Disorder, Major psychology, Female, Follow-Up Studies, Humans, Male, Middle Aged, Pilot Projects, Serotonergic Neurons metabolism, Statistics, Nonparametric, Suicidal Ideation, Time Factors, Depressive Disorder, Major physiopathology, Evoked Potentials, Auditory physiology, Loudness Perception physiology, Serotonergic Neurons physiology, Suicide, Attempted

Abstract

Loudness dependence of auditory evoked potentials (LDAEP) is a validated in vivo marker of central serotonergic function. We aimed at measuring serotonergic activity in a follow-up study of suicidal patients. It should be investigated whether suicide attempts or suicidal states cause changes in the LDAEP. Thirteen patients (mean age, 40.9 ± 11.3 years; age range, 20-61, 6 male) with a major depressive episode who had attempted suicide or had suicidal plans (Hamilton Depression Rating Scale item 3 [suicidality] ≥3) were included in the study. LDAEP and psychometric measurements took place about 2, 5, 9 and 16 days after attempted suicide or suicidal action. On day 9, LDAEP was significantly higher compared to day 2 and day 16; there was a similar tendency compared to day 5. Instability of central serotonergic function is suggested resulting in reduced serotonergic activity about 1 week after suicide attempt. Further studies are necessary that include larger samples in order to distinguish between different psychiatric diseases and to consider confounding factors like gender, smoking, medication, impulsivity or lethality of suicidal action.

Published

2012

174. Temporary suppression of tinnitus by modulated sounds.

Author

Reavis KM, Rothholtz VS, Tang Q, Carroll JA, Djalilian H, and Zeng FG

Subjects

Adult, Aged, Audiometry, Pure-Tone, Auditory Perception physiology, Female, Humans, Logistic Models, Loudness Perception physiology, Male, Middle Aged, Perceptual Masking physiology, Treatment Outcome, Acoustic Stimulation, Auditory Threshold physiology, Outcome Assessment, Health Care, Sound, Tinnitus physiopathology, Tinnitus therapy

Abstract

Despite high prevalence of tinnitus and its impact on quality life, there is no cure for tinnitus at present. Here, we report an effective means to temporarily suppress tinnitus by amplitude- and frequency-modulated tones. We systematically explored the interaction between subjective tinnitus and 17 external sounds in 20 chronic tinnitus sufferers. The external sounds included traditionally used unmodulated stimuli such as pure tones and white noise and dynamically modulated stimuli known to produce sustained neural synchrony in the central auditory pathway. All external sounds were presented in a random order to all subjects and at a loudness level that was just below tinnitus loudness. We found some tinnitus suppression in terms of reduced loudness by at least one of the 17 stimuli in 90% of the subjects, with the greatest suppression by amplitude-modulated tones with carrier frequencies near the tinnitus pitch for tinnitus sufferers with relatively normal loudness growth. Our results suggest that, in addition to a traditional masking approach using unmodulated pure tones and white noise, modulated sounds should be used for tinnitus suppression because they may be more effective in reducing hyperactive neural activities associated with tinnitus. The long-term effects of the modulated sounds on tinnitus and the underlying mechanisms remain to be investigated.

Published

2012

175. Enhancement of temporal cues to pitch in cochlear implants: effects on pitch ranking.

Author

Vandali AE and van Hoesel RJ

Subjects

Analysis of Variance, Cues, Female, Humans, Loudness Perception physiology, Male, Music, Perceptual Masking physiology, Phonetics, Cochlear Implants, Deafness physiopathology, Pitch Discrimination physiology

Abstract

The abilities to hear changes in pitch for sung vowels and understand speech using an experimental sound coding strategy (eTone) that enhanced coding of temporal fundamental frequency (F0) information were tested in six cochlear implant users, and compared with performance using their clinical (ACE) strategy. In addition, rate- and modulation rate-pitch difference limens (DLs) were measured using synthetic stimuli with F0s below 300 Hz to determine psychophysical abilities of each subject and to provide experience in attending to rate cues for the judgment of pitch. Sung-vowel pitch ranking tests for stimuli separated by three semitones presented across an F0 range of one octave (139-277 Hz) showed a significant benefit for the experimental strategy compared to ACE. Average d-prime (d') values for eTone (d' = 1.05) were approximately three time larger than for ACE (d' = 0.35). Similar scores for both strategies in the speech recognition tests showed that coding of segmental speech information by the experimental strategy was not degraded. Average F0 DLs were consistent with results from previous studies and for all subjects were less than or equal to approximately three semitones for F0s of 125 and 200 Hz.

Published

2012

176. Feasibility of an objective electrophysiological loudness scaling: a kernel-based novelty detection approach.

Author

Mariam M, Delb W, Schick B, and Strauss DJ

Subjects

Acoustic Stimulation, Adult, Electroencephalography, Female, Humans, Male, Pilot Projects, Auditory Threshold physiology, Evoked Potentials, Auditory physiology, Habituation, Psychophysiologic physiology, Loudness Perception physiology, Wavelet Analysis

Abstract

Objective: The objective of our research is to structure a foundation for an electrophysiological loudness scaling measurement, in particular to estimate an uncomfortable loudness (UCL) level by using the hybrid wavelet-kernel novelty detection (HWND)., Methods and Materials: Late auditory evoked potentials (LAEPs) were obtained from 20 normal hearing adults. These LAEPs were stimulated by 4 intensity levels (60 decibel (dB) sound pressure level (SPL), 70 dB SPL, 80 dB SPL, and 90 dB SPL). We have extracted the habituation correlates in LAEPs by using HWND. For this, we employed a lattice structure-based wavelet frame decompositions for feature extraction combined with a kernel-based novelty detector., Results: The group results showed that the habituation correlates degrees, i.e., relative changes within the sweep sequences, were significantly different among 60 dB SPL, 70 dB SPL, 80 dB SPL, and 90 dB SPL stimulation level, independently from the intensity related amplitude information in the averaged LAEPs. At these particular intensities, 60% of the subjects show the correlation between the novelty measures and the stimulation levels resembles a loudness scaling function, in reverse. In this paper, we have found a correlation in between the novelty measures and loudness perception as well. We have found that high ranges of loudness levels such as loud, upper level and too loud show generally 4.88% of novelty measures and comfortable ranges of loudness levels, i.e., soft, comfortable but soft, comfortable loud and comfortable but loud are generally have 12.29% of novelty measures. Additionally, we demonstrated that our sweep-to-sweep basis of post processing scheme is reliable for habituation extraction and offers an advantage of reducing experimental time as the proposed scheme need less than 20% of single sweeps in comparison to the amount that are commonly used in arithmetical average for a meaningful result., Conclusions: We assessed the feasibility of habituation correlates for an objective loudness scaling. With respect to this first feasibility study, the presented results are promising when using the described signal processing and machine learning methodology. For the group results, the novelty measures approach is able to discriminate 60 dB, 70 dB, 80 dB and 90 dB stimulated sweeps. In addition, a correlation between the novelty measures and the subjective loudness scaling is observed. However, more loudness perception and frequency specific experiments need to be conducted to determine the UCL novelty measures threshold as well as clinically oriented studies are necessary to evaluate whether this approach might be used in the objective hearing instrument fitting procedures., (Copyright © 2012 Elsevier B.V. All rights reserved.)

Published

2012

177. The sound of music: differentiating musicians using a fast, musical multi-feature mismatch negativity paradigm.

Author

Vuust P, Brattico E, Seppänen M, Näätänen R, and Tervaniemi M

Subjects

Acoustic Stimulation methods, Adult, Analysis of Variance, Electroencephalography, Female, Humans, Male, Middle Aged, Psychoacoustics, Reaction Time, Young Adult, Brain Mapping, Contingent Negative Variation physiology, Evoked Potentials, Auditory physiology, Loudness Perception physiology, Music, Pitch Perception physiology

Abstract

Musicians' skills in auditory processing depend highly on instrument, performance practice, and on level of expertise. Yet, it is not known though whether the style/genre of music might shape auditory processing in the brains of musicians. Here, we aimed at tackling the role of musical style/genre on modulating neural and behavioral responses to changes in musical features. Using a novel, fast and musical sounding multi-feature paradigm, we measured the mismatch negativity (MMN), a pre-attentive brain response, to six types of musical feature change in musicians playing three distinct styles of music (classical, jazz, rock/pop) and in non-musicians. Jazz and classical musicians scored higher in the musical aptitude test than band musicians and non-musicians, especially with regards to tonal abilities. These results were extended by the MMN findings: jazz musicians had larger MMN-amplitude than all other experimental groups across the six different sound features, indicating a greater overall sensitivity to auditory outliers. In particular, we found enhanced processing of pith and sliding up to pitches in jazz musicians only. Furthermore, we observed a more frontal MMN to pitch and location compared to the other deviants in jazz musicians and left lateralization of the MMN to timbre in classical musicians. These findings indicate that the characteristics of the style/genre of music played by musicians influence their perceptual skills and the brain processing of sound features embedded in a musical context. Musicians' brain is hence shaped by the type of training, musical style/genre, and listening experiences., (Copyright © 2012 Elsevier Ltd. All rights reserved.)

Published

2012

178. Application of the envelope difference index to spectrally sparse speech.

Author

Souza P, Hoover E, and Gallun F

Subjects

Adolescent, Adult, Auditory Threshold, Cues, Follow-Up Studies, Humans, Loudness Perception physiology, Models, Theoretical, Reference Values, Sound Spectrography methods, Sound Spectrography standards, Speech Discrimination Tests, Young Adult, Hearing Aids, Phonetics, Speech Acoustics, Speech Perception physiology

Abstract

Purpose: Amplitude compression is a common hearing aid processing strategy that can improve speech audibility and loudness comfort but also has the potential to alter important cues carried by the speech envelope. In previous work, a measure of envelope change, the Envelope Difference Index (EDI; Fortune, Woodruff, & Preves, 1994), was moderately related to recognition of spectrally robust consonants. This follow-up study investigated the relationship between the EDI and recognition of spectrally sparse consonants., Method: Stimuli were vowel-consonant-vowel tokens processed to reduce spectral cues. Compression parameters were chosen to achieve a range of EDI values. Recognition was measured for 20 listeners with normal hearing., Results: Both overall recognition and perception of consonant features were reduced at higher EDI values. Similar effects were noted with noise-vocoded and sine-vocoded processing and regardless of whether periodicity cues were available., Conclusion: The data provide information about the acceptable limits of envelope distortion under constrained conditions. These limits can be used to consider the impact of envelope distortions in situations where other cues are available to varying extents.

Published

2012

179. Neural coding of sound intensity and loudness in the human auditory system.

Author

Röhl M and Uppenkamp S

Subjects

Adolescent, Adult, Attention, Humans, Magnetic Resonance Imaging, Male, Sound, Young Adult, Auditory Cortex physiology, Geniculate Bodies physiology, Inferior Colliculi physiology, Loudness Perception physiology

Abstract

Inter-individual differences in loudness sensation of 45 young normal-hearing participants were employed to investigate how and at what stage of the auditory pathway perceived loudness, the perceptual correlate of sound intensity, is transformed into neural activation. Loudness sensation was assessed by categorical loudness scaling, a psychoacoustical scaling procedure, whereas neural activation in the auditory cortex, inferior colliculi, and medial geniculate bodies was investigated with functional magnetic resonance imaging (fMRI). We observed an almost linear increase of perceived loudness and percent signal change from baseline (PSC) in all examined stages of the upper auditory pathway. Across individuals, the slope of the underlying growth function for perceived loudness was significantly correlated with the slope of the growth function for the PSC in the auditory cortex, but not in subcortical structures. In conclusion, the fMRI correlate of neural activity in the auditory cortex as measured by the blood oxygen level-dependent effect appears to be more a linear reflection of subjective loudness sensation rather than a display of physical sound pressure level, as measured using a sound-level meter.

Published

2012

180. The effects of sound level and vibration magnitude on the relative discomfort of noise and vibration.

Author

Huang Y and Griffin MJ

Subjects

Acoustic Stimulation, Adult, Female, Humans, Judgment, Male, Physical Stimulation, Young Adult, Loudness Perception physiology, Noise adverse effects, Vibration adverse effects

Abstract

The relative discomfort caused by noise and vibration, how this depends on the level of noise and the magnitude of vibration, and whether the noise and vibration are presented simultaneously or sequentially has been investigated in a laboratory study with 20 subjects. Noise and vertical vibration were reproduced with all 49 combinations of 7 levels of noise and 7 magnitudes of vibration to allow the discomfort caused by one of the stimuli to be judged relative to the other stimulus using magnitude estimation. In four sessions, subjects judged noise relative to vibration and vibration relative to noise, with both simultaneous and sequential presentations of the stimuli. The equivalence of noise and vibration was not greatly dependent on whether the stimuli were simultaneous or sequential, but highly dependent on whether noise was judged relative to vibration or vibration was judged relative to noise. When judging noise, higher magnitude vibrations appeared to mask the discomfort caused by low levels of noise. When judging vibration, higher level noises appeared to mask the discomfort caused by low magnitudes of vibration. The judgment of vibration discomfort was more influenced by noise than the judgment of noise discomfort was influenced by vibration.

Published

2012

181. Relationships between electrically evoked potentials and loudness growth in bilateral cochlear implant users.

Author

Kirby B, Brown C, Abbas P, Etler C, and O'Brien S

Subjects

Action Potentials physiology, Adult, Aged, Auditory Cortex physiology, Auditory Pathways physiology, Deafness physiopathology, Deafness therapy, Female, Humans, Male, Middle Aged, Psychoacoustics, Sound Localization physiology, Telemetry, Cochlear Implantation methods, Evoked Potentials, Auditory, Brain Stem physiology, Hearing Loss, Bilateral physiopathology, Hearing Loss, Bilateral therapy, Loudness Perception physiology

Abstract

Objectives: The goals of this study were (1) to describe the relationship between electrically evoked compound action potential (ECAP) and electrically evoked auditory brainstem response (EABR) amplitude growth functions and loudness growth functions in bilateral cochlear implant (CI) users, and (2) to determine whether matching the stimulus levels in the two ears of bilateral CI users based on equal ECAP amplitude, EABR amplitude, or current level resulted in the smallest discrepancy in loudness rating across the two ears., Design: Ten adult, bilateral CI users participated in this study. The stimulus used to elicit loudness judgments and generate ECAP and EABR growth functions was a train of biphasic current pulses (32 μs/phase) presented at a rate of 23 pps. Loudness growth functions were obtained with a method of constant stimuli. ECAPs were measured using the implant telemetry system. EABR growth functions were recorded using surface electrodes and standard averaging techniques. Both ears of each subject were tested. For each ear, ECAP, EABR, and loudness functions were recorded using both an apical and basal stimulating electrode. Both the physiologic and psychophysical growth functions were fit using linear regression techniques., Results: Comparison of the regression equations obtained for the two ears revealed that stimulus levels that yielded approximately equal ECAP amplitudes in the two ears were judged to differ in loudness, on average, by 20% for electrode 3 and 14% for electrode 13. Stimulation levels that evoked similar amplitude EABRs differed in loudness, on average, by 50% for electrode 3 and 13% for electrode 13. Matched stimulus current levels were judged to differ in loudness, on average, by 14% for electrode 3 and 16% for electrode 13. No significant differences in loudness discrepancy across ears derived from equal amplitude ECAP, EABR, or matched current levels were found., Conclusions: This study demonstrated that stimuli that evoke equal amplitude neural responses in both ears of a bilateral CI user or which are matched in current level cannot be assumed to be perceived as equally loud. No statistically significant differences in accuracy were found between ECAP, EABR, or matched current levels or between the basal and apical electrode in approximations of equal loudness.

Published

2012

182. The annoyance of snoring and psychoacoustic parameters: a step towards an objective measurement.

Author

Rohrmeier C, Herzog M, Haubner F, and Kuehnel TS

Subjects

Adult, Aged, Female, Follow-Up Studies, Humans, Male, Middle Aged, Polysomnography, Psychometrics methods, Snoring diagnosis, Sound Spectrography, Young Adult, Loudness Perception physiology, Psychoacoustics, Snoring physiopathology

Abstract

The aim of this study was to find out whether objective analysis of snoring sounds (sound pressure level and psychoacoustic parameters) correlates with the subjective rating by participants with respect to perceived annoyance and hence whether it is useful. 43 participants, aged 22-65 years with normal hearing, were asked to rate 60 snoring sounds from simple and obstructive snorers according to their level of annoyance. A correlation analysis according to Spearman was then performed on objectively calculated parameters. These were the A-weighted sound pressure level, the psychoacoustic parameters of loudness, sharpness, fluctuation strength and roughness and psychoacoustic annoyance (PA) calculated from those parameters. The subjective ratings showed high, highly significant correlations with, in particular, the mean A-weighted sound pressure level (r = 0.88; p < 0.01), the 5th percentile of psychoacoustic loudness (r = 0.89; p < 0.01) and psychoacoustic annoyance (r = 0.80; p < 0.01). These parameters seem to provide information about the degree of annoyance that is objectively measurable and independent of the snorer's bed partner. Further studies should follow in order to confirm these results, find out their generalizability and establish reference values.

Published

2012

183. Binaural loudness summation for speech presented via earphones and loudspeaker with and without visual cues.

Author

Epstein M and Florentine M

Subjects

Acoustics instrumentation, Adult, Female, Humans, Male, Phonetics, Photic Stimulation methods, Pitch Perception physiology, Young Adult, Cues, Loudness Perception physiology, Speech Perception physiology

Abstract

Preliminary data [M. Epstein and M. Florentine, Ear. Hear. 30, 234-237 (2009)] obtained using speech stimuli from a visually present talker heard via loudspeakers in a sound-attenuating chamber indicate little difference in loudness when listening with one or two ears (i.e., significantly reduced binaural loudness summation, BLS), which is known as "binaural loudness constancy." These data challenge current understanding drawn from laboratory measurements that indicate a tone presented binaurally is louder than the same tone presented monaurally. Twelve normal listeners were presented recorded spondees, monaurally and binaurally across a wide range of levels via earphones and a loudspeaker with and without visual cues. Statistical analyses of binaural-to-monaural ratios of magnitude estimates indicate that the amount of BLS is significantly less for speech presented via a loudspeaker with visual cues than for stimuli with any other combination of test parameters (i.e., speech presented via earphones or a loudspeaker without visual cues, and speech presented via earphones with visual cues). These results indicate that the loudness of a visually present talker in daily environments is little affected by switching between binaural and monaural listening. This supports the phenomenon of binaural loudness constancy and underscores the importance of ecological validity in loudness research.

Published

2012

184. Role of community tolerance level (CTL) in predicting the prevalence of the annoyance of road and rail noise.

Author

Schomer P, Mestre V, Fidell S, Berry B, Gjestland T, Vallet M, and Reid T

Subjects

Attitude to Health, Environmental Exposure adverse effects, Humans, Loudness Perception physiology, Time Factors, Vibration, Automobiles, Noise, Transportation adverse effects, Personal Satisfaction, Public Opinion, Railroads

Abstract

Fidell et al. [(2011), J. Acoust. Soc. Am. 130(2), 791-806] have shown (1) that the rate of growth of annoyance with noise exposure reported in attitudinal surveys of the annoyance of aircraft noise closely resembles the exponential rate of change of loudness with sound level, and (2) that the proportion of a community highly annoyed and the variability in annoyance prevalence rates in communities are well accounted for by a simple model with a single free parameter: a community tolerance level (abbreviated CTL, and represented symbolically in mathematical expressions as L(ct)), expressed in units of DNL. The current study applies the same modeling approach to predicting the prevalence of annoyance of road traffic and rail noise. The prevalence of noise-induced annoyance of all forms of transportation noise is well accounted for by a simple, loudness-like exponential function with community-specific offsets. The model fits all of the road traffic findings well, but the prevalence of annoyance due to rail noise is more accurately predicted separately for interviewing sites with and without high levels of vibration and/or rattle.

Published

2012

185. Relating binaural pitch perception to the individual listener's auditory profile.

Author

Santurette S and Dau T

Subjects

Acoustic Impedance Tests methods, Adult, Audiometry, Pure-Tone, Auditory Threshold physiology, Cochlear Diseases physiopathology, Cognition physiology, Ear, Middle physiology, Humans, Loudness Perception physiology, Memory physiology, Otoacoustic Emissions, Spontaneous physiology, Perceptual Masking physiology, Reaction Time, Hearing physiology, Hearing Loss, Sensorineural physiopathology, Pitch Discrimination physiology

Abstract

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.

Published

2012

186. Consequences of broad auditory filters for identification of multichannel-compressed vowels.

Author

Souza P, Wright R, and Bor S

Subjects

Acoustic Stimulation methods, Adult, Aged, Aged, 80 and over, Auditory Threshold physiology, Cohort Studies, Hearing physiology, Humans, Loudness Perception physiology, Middle Aged, Hearing Aids, Hearing Loss, Sensorineural physiopathology, Hearing Loss, Sensorineural rehabilitation, Phonetics, Speech Perception physiology

Abstract

Purpose: In view of previous findings (Bor, Souza, & Wright, 2008) that some listeners are more susceptible to spectral changes from multichannel compression (MCC) than others, this study addressed the extent to which differences in effects of MCC were related to differences in auditory filter width., Method: Listeners were recruited in 3 groups: listeners with flat sensorineural loss, listeners with sloping sensorineural loss, and a control group of listeners with normal hearing. Individual auditory filter measurements were obtained at 500 and 2000 Hz. The filter widths were related to identification of vowels processed with 16-channel MCC and with a control (linear) condition., Results: Listeners with flat loss had broader filters at 500 Hz but not at 2000 Hz compared with listeners with sloping loss. Vowel identification was poorer for MCC compared with linear amplification. Listeners with flat loss made more errors than listeners with sloping loss, and there was a significant relationship between filter width and the effects of MCC., Conclusions: Broadened auditory filters can reduce the ability to process amplitude-compressed vowel spectra. This suggests that individual frequency selectivity is a factor that influences benefit of MCC when a high number of compression channels are used.

Published

2012

187. Is a change in vocal loudness a first step towards becoming a medical doctor?

Author

Kiese-Himmel C, Himmel W, Rodenstock M, and Scherer M

Subjects

Adolescent, Adult, Cross-Sectional Studies, Female, Follow-Up Studies, Humans, Male, Psychoacoustics, Sex Factors, Young Adult, Career Choice, Education, Medical, Undergraduate, Loudness Perception physiology, Social Dominance, Speech Acoustics, Students, Medical psychology, Voice Quality physiology

Abstract

Questions Under Study: Some evidence suggests that a loud voice is a core characteristic of medical professionals. It is unknown whether medical students talk louder than their non-medical peers and, if so, whether they commence their studies with a loud voice, representing a characteristic of admission, or whether sound pressure level changes during education, reflecting model learning., Methods: We performed a cross-sectional observation study with 206 students (57% female), stratified in 4 groups (medical and non-medical students as freshmen and fifth-year students). Habitual loudness was defined as a student's sound pressure level, measured with a standardised sound level meter on basis of 2 vocal tasks. The hypothesis was tested in a 2-way analysis of variance, with year of study (first vs. fifth year) and field by study (medicine vs. non-medicine) as main factors., Results: The sound pressure level of freshmen in medicine was, on average, 64.4 dB (SD 3.0), that of fifth-year medical students was 66.3 dB (3.7). The respective scores of non-medical students were 65.3 (SD 2.7) for freshmen and 64.0 (3.4) for fifth-year students, resulting in a significant interaction between field of study and years of study (F = 12.7; p = 0.0005)., Conclusions: The findings of this preliminary study present some evidence that medical students, in contrast to their non-medical peers, learn to raise vocal loudness during their education in medical school. Habitual loudness of medical students, as a way to gain professional dominance and a possible risk for hoarseness in later life, deserves more attention.

Published

2012

188. Auditory adaptation to sound intensity in conscious rats: 2-[F-18]-fluoro-2-deoxy-D-glucose PET study.

Author

Jang DP, Lee KM, Lee SY, Oh JH, Park CW, Kim IY, Kim YB, and Cho ZH

Subjects

Acoustic Stimulation methods, Animals, Auditory Pathways anatomy & histology, Auditory Pathways diagnostic imaging, Fluorodeoxyglucose F18, Male, Rats, Rats, Sprague-Dawley, Sound, Adaptation, Physiological physiology, Auditory Pathways metabolism, Loudness Perception physiology, Positron-Emission Tomography methods

Abstract

Despite the importance of the adaptive process for discriminating the broad range of sound intensity, there have been few systemic investigations targeting the auditory mechanisms. In this study, the adaptation effect of sound intensity on the change in glucose metabolism in rat brains was examined using a PET technique. In the first experiment, broadband white noise sound (40, 60, 80, or 100 dB sound pressure level) was given for 30 min after an 2-[F-18]-fluoro-2-deoxy-D-glucose injection in an awake condition. In the second experiment, sound stimuli with an intensity modulation of 0, 0.5, and 5.0 Hz in frequency and at three intensity levels were used for examining the metabolism change according to the short time scale variation of the sound intensity. As a result, the metabolic activities in the bilateral cochlear nucleus, superior olivary complexes, and inferior colliculus were proportional to the sound intensity level, whereas the bilateral auditory cortical areas unexpectedly decreased as the sound intensity level increased in the first experiment. In the second experiment, the glucose metabolism in the auditory cortex was higher at 0.5 and 5.0 Hz modulation frequency than the 0.0 Hz modulation frequency, while retaining an inverse relationship with the sound intensity. The metabolism in inferior colliculus was higher at 5.0 Hz modulation frequency than 0.0 and 0.5 Hz modulation frequencies. Taken together, the auditory cortex metabolism seemed to be actively adapted to the average sound intensity, which indicates that it plays an important role in processing the broad range to sound intensity more than the other nucleus of the auditory pathway. Especially, this study demonstrated that the sound intensity-dependent glucose metabolism can be seen in a small rodent's brain stem level using 2-[F-18]-fluoro-2-deoxy-D-glucose PET functional neuroimaging.

Published

2012

189. Place-pitch manipulations with cochlear implants.

Author

Macherey O and Carlyon RP

Subjects

Acoustic Stimulation, Analysis of Variance, Humans, Loudness Perception physiology, Models, Anatomic, Psychometrics, Cochlear Implants, Pitch Discrimination physiology

Abstract

Pitch can be conveyed to cochlear implant listeners via both place of excitation and temporal cues. The transmission of place cues may be hampered by several factors, including limitations on the insertion depth and number of implanted electrodes, and the broad current spread produced by monopolar stimulation. The following series of experiments investigate several methods to partially overcome these limitations. Experiment 1 compares two recently published techniques that aim to activate more apical fibers than produced by monopolar or bipolar stimulation of the most apical contacts. The first technique (phantom stimulation) manipulates the current spread by simultaneously stimulating two electrodes with opposite-polarity pulses of different amplitudes. The second technique manipulates the neural spread of excitation by using asymmetric pulses and exploiting the polarity-sensitive properties of auditory nerve fibers. The two techniques yielded similar results and were shown to produce lower place-pitch percepts than stimulation of monopolar and bipolar symmetric pulses. Furthermore, combining these two techniques may be advantageous in a clinical setting. Experiment 2 proposes a method to create place pitches intermediate to those produced by physical electrodes by using charge-balanced asymmetric pulses in bipolar mode with different degrees of asymmetry., (© 2012 Acoustical Society of America)

Published

2012

190. Forward masking as a method of measuring place specificity of neural excitation in cochlear implants: a review of methods and interpretation.

Author

McKay CM

Subjects

Acoustic Stimulation methods, Cochlear Nerve physiology, Electric Stimulation methods, Humans, Loudness Perception physiology, Space Perception physiology, Speech Perception physiology, Auditory Threshold physiology, Cochlear Implants, Neurons physiology, Perceptual Masking physiology

Abstract

This paper reviews the psychophysical forward masking methods that have been used to investigate place specificity in cochlear implantees. These experiments are relevant for investigating whether the individual variability in outcomes for people using the same device can be explained by individual variations in frequency resolution or whether place specificity is affected by different modes of stimulation (such as bipolar, monopolar or tripolar) in the same person. Unfortunately, there has been no consensus about the methods used to derive electrical forward masking functions, or in the way that they are interpreted in relation to place specificity. Here, the different methods are critically examined to provide insight into the optimal methods that should be used to measure and interpret spatial forward masking functions in electric hearing. It is shown that, in order to separate the temporal effects of masking decay from the place-specificity information, different analyses of the functions are needed depending on whether a fixed-probe or fixed-masker method is employed. The effects of unit of measurement on specificity measures and the effects of subject listening strategy on the forward masked functions are also discussed., (© 2012 Acoustical Society of America)

Published

2012

191. Variations in carrier pulse rate and the perception of amplitude modulation in cochlear implant users.

Author

Green T, Faulkner A, and Rosen S

Subjects

Aged, Auditory Threshold physiology, Cochlear Implantation instrumentation, Cochlear Nerve physiology, Cues, Discrimination, Psychological physiology, Electric Stimulation methods, Humans, Loudness Perception physiology, Middle Aged, Auditory Perception physiology, Cochlear Implantation methods, Cochlear Implants, Deafness physiopathology, Deafness rehabilitation

Abstract

Objectives: A major focus of recent attempts to enhance cochlear implant (CI) systems has been to increase the rate at which pulses are delivered to the electrode array. One basis for these attempts has been the expectation that faster stimulation rates would lead to an enhanced representation of temporal modulation information. However, there is recent physiological and behavioral evidence to suggest that the reverse may be the case. Here, the effects of stimulation rate on the perception of amplitude modulation were assessed using both modulation detection and modulation frequency discrimination tasks for a range of pulse rates extending considerably higher than the highest rate tested in previous studies and for different speech-relevant modulation frequencies., Design: Detection of sinusoidal amplitude modulation was assessed in five CI users using monopolar pulse trains presented to a single electrode at rates of 482, 723, 1447, 2894, and 5787 pulses per second (pps). Adaptive procedures were used to find the minimal detectable modulation depth at modulation frequencies of 10 and 100 Hz and at carrier levels of 25%, 50%, and 75% of the electrode's dynamic range. Discrimination of modulation frequency was examined for the same range of pulse rates for the highest carrier level. Similar adaptive procedures determined the minimum increase in modulation frequency that could be detected relative to reference modulation frequencies of 10, 100, and 200 Hz. In both tasks, level roving was implemented to minimize possible loudness cues., Results: Consistent with previous evidence, modulation detection thresholds were better for higher carrier levels and lower modulation frequencies. When modulation depth at threshold was expressed in terms of the ratio of the depth of the modulation and the carrier level in dB (i.e., 20 log m), performance was significantly better at lower pulse rates. However, when modulation depth was expressed relative to dynamic range, the effect of pulse rate was no longer significant, reflecting the fact that dynamic range increases with pulse rate. Modulation frequency discrimination clearly worsened with increasing modulation frequency, but there was no significant effect of pulse rate., Conclusions: In contrast to some recent evidence, no clearly harmful effect of higher pulse rates on modulation perception was found. However, even with very fast stimulation rates, tested over a wide range of modulation frequencies and with two different tasks, there is no evidence of benefit from faster stimulation rates in the perception of amplitude modulation.

Published

2012

192. Comodulation masking release in speech identification with real and simulated cochlear-implant hearing.

Author

Ihlefeld A, Shinn-Cunningham BG, and Carlyon RP

Subjects

Acoustic Stimulation, Adolescent, Analysis of Variance, Auditory Threshold physiology, Humans, Loudness Perception physiology, Young Adult, Cochlear Implants, Hearing Loss, Sensorineural physiopathology, Noise, Perceptual Masking physiology, Speech Perception physiology

Abstract

For normal-hearing (NH) listeners, masker energy outside the spectral region of a target signal can improve target detection and identification, a phenomenon referred to as comodulation masking release (CMR). This study examined whether, for cochlear implant (CI) listeners and for NH listeners presented with a "noise vocoded" CI simulation, speech identification in modulated noise is improved by a co-modulated flanking band. In Experiment 1, NH listeners identified noise-vocoded speech in a background of on-target noise with or without a flanking narrow band of noise outside the spectral region of the target. The on-target noise and flanker were either 16-Hz square-wave modulated with the same phase or were unmodulated; the speech was taken from a closed-set corpus. Performance was better in modulated than in unmodulated noise, and this difference was slightly greater when the comodulated flanker was present, consistent with a small CMR of about 1.7 dB for noise-vocoded speech. Experiment 2, which tested CI listeners using the same speech materials, found no advantage for modulated versus unmodulated maskers and no CMR. Thus although NH listeners can benefit from CMR even for speech signals with reduced spectro-temporal detail, no CMR was observed for CI users., (© 2012 Acoustical Society of America)

Published

2012

193. Unanesthetized auditory cortex exhibits multiple codes for gaps in cochlear implant pulse trains.

Author

Kirby AE and Middlebrooks JC

Subjects

Acoustic Stimulation methods, Action Potentials physiology, Anesthesia, Animals, Auditory Threshold physiology, Female, Guinea Pigs, Loudness Perception physiology, Male, Reaction Time physiology, Auditory Cortex physiology, Cochlear Implantation, Deafness physiopathology, Deafness therapy, Wakefulness

Abstract

Cochlear implant listeners receive auditory stimulation through amplitude-modulated electric pulse trains. Auditory nerve studies in animals demonstrate qualitatively different patterns of firing elicited by low versus high pulse rates, suggesting that stimulus pulse rate might influence the transmission of temporal information through the auditory pathway. We tested in awake guinea pigs the temporal acuity of auditory cortical neurons for gaps in cochlear implant pulse trains. Consistent with results using anesthetized conditions, temporal acuity improved with increasing pulse rates. Unlike the anesthetized condition, however, cortical neurons responded in the awake state to multiple distinct features of the gap-containing pulse trains, with the dominant features varying with stimulus pulse rate. Responses to the onset of the trailing pulse train (Trail-ON) provided the most sensitive gap detection at 1,017 and 4,069 pulse-per-second (pps) rates, particularly for short (25 ms) leading pulse trains. In contrast, under conditions of 254 pps rate and long (200 ms) leading pulse trains, a sizeable fraction of units demonstrated greater temporal acuity in the form of robust responses to the offsets of the leading pulse train (Lead-OFF). Finally, TONIC responses exhibited decrements in firing rate during gaps, but were rarely the most sensitive feature. Unlike results from anesthetized conditions, temporal acuity of the most sensitive units was nearly as sharp for brief as for long leading bursts. The differences in stimulus coding across pulse rates likely originate from pulse rate-dependent variations in adaptation in the auditory nerve. Two marked differences from responses to acoustic stimulation were: first, Trail-ON responses to 4,069 pps trains encoded substantially shorter gaps than have been observed with acoustic stimuli; and second, the Lead-OFF gap coding seen for <15 ms gaps in 254 pps stimuli is not seen in responses to sounds. The current results may help to explain why moderate pulse rates around 1,000 pps are favored by many cochlear implant listeners.

Published

2012

194. Individual differences in the biomechanical effect of loudness and tempo on upper-limb movements during repetitive piano keystrokes.

Author

Furuya S, Aoki T, Nakahara H, and Kinoshita H

Subjects

Adult, Cumulative Trauma Disorders physiopathology, Elbow Joint physiology, Female, Finger Joint physiology, Humans, Isometric Contraction physiology, Isotonic Contraction physiology, Male, Muscle, Skeletal physiology, Occupational Diseases physiopathology, Shoulder Joint physiology, Wrist Joint physiology, Arm physiology, Biomechanical Phenomena physiology, Individuality, Loudness Perception physiology, Music, Psychomotor Performance physiology, Sound Spectrography, Time Perception physiology

Abstract

The present study addressed the effect of loudness and tempo on kinematics and muscular activities of the upper extremity during repetitive piano keystrokes. Eighteen pianists with professional music education struck two keys simultaneously and repetitively with a combination of four loudness levels and four tempi. The results demonstrated a significant interaction effect of loudness and tempo on peak angular velocity for the shoulder, elbow, wrist and finger joints, mean muscular activity for the corresponding flexors and extensors, and their co-activation level. The interaction effect indicated greater increases with tempo when eliciting louder tones for all joints and muscles except for the elbow velocity showing a greater decrease with tempo. Multiple-regression analysis and K-means clustering further revealed that 18 pianists were categorized into three clusters with different interaction effects on joint kinematics. These clusters were characterized by either an elbow-velocity decrease and a finger-velocity increase, a finger-velocity decrease with increases in shoulder and wrist velocities, or a large elbow-velocity decrease with a shoulder-velocity increase when increasing both loudness and tempo. Furthermore, the muscular load considerably differed across the clusters. These findings provide information to determine muscles with the greatest potential risk of playing-related disorders based on movement characteristics of individual pianists., (Copyright © 2011 Elsevier B.V. All rights reserved.)

Published

2012

195. Reliability of distortion-product otoacoustic emissions and their relation to loudness.

Author

Thorson MJ, Kopun JG, Neely ST, Tan H, and Gorga MP

Subjects

Acoustic Impedance Tests methods, Acoustic Stimulation, Adolescent, Adult, Aged, Audiometry, Pure-Tone methods, Case-Control Studies, Child, Humans, Middle Aged, Multivariate Analysis, Pitch Discrimination physiology, Reproducibility of Results, Young Adult, Hearing Loss physiopathology, Loudness Perception physiology, Otoacoustic Emissions, Spontaneous physiology, Perceptual Distortion physiology

Abstract

The reliability of distortion-product otoacoustic emission (DPOAE) measurements and their relation to loudness measurements was examined in 16 normal-hearing subjects and 58 subjects with hearing loss. The level of the distortion product (L(d)) was compared across two sessions and resulted in correlations that exceeded 0.90. The reliability of DPOAEs was less when parameters from nonlinear fits to the input/output (I/O) functions were compared across visits. Next, the relationship between DPOAE I/O parameters and the slope of the low-level portion of the categorical loudness scaling (CLS) function (soft slope) was assessed. Correlations of 0.65, 0.74, and 0.81 at 1, 2, and 4 kHz were observed between CLS soft slope and combined DPOAE parameters. Behavioral threshold had correlations of 0.82, 0.83, and 0.88 at 1, 2, and 4 kHz with CLS soft slope. Combining DPOAEs and behavioral threshold provided little additional information. Lastly, a multivariate approach utilizing the entire DPOAE I/O function was used to predict the CLS rating for each input level (dB SPL). Standard error of the estimate when using this method ranged from 2.4 to 3.0 categorical units (CU), suggesting that DPOAE I/O functions can predict CLS measures within the CU step size used in this study (5)., (© 2012 Acoustical Society of America)

Published

2012

196. Characteristics of detection thresholds and maximum comfortable loudness levels as a function of pulse rate in human cochlear implant users.

Author

Zhou N, Xu L, and Pfingst BE

Subjects

Acoustic Stimulation, Adult, Aged, Animals, Deafness physiopathology, Deafness therapy, Electric Stimulation, Guinea Pigs, Heart Rate physiology, Humans, Middle Aged, Species Specificity, Auditory Threshold physiology, Cochlear Implants, Loudness Perception physiology

Abstract

The ability of an implanted ear to integrate multiple pulses, as measured by the slopes of detection threshold level (T level) versus pulse rate functions, may reflect cochlear health in the cochlea, as suggested by previous animal studies (Kang et al., 2010; Pfingst et al., 2011). In the current study, we examined the slopes of T level versus pulse rate functions in human subjects with cochlear implants. Typically, T levels decrease as a function of pulse rate, consistent with a multipulse integration mechanism. The magnitudes of the slopes of the T level versus pulse rate functions obtained from the human subjects were comparable to those reported in the animal studies. The slopes varied across stimulation sites, but did not change systematically along the tonotopic axis. This suggests that the slopes are dependent on local conditions near the individual stimulation sites. The characteristics of these functions were also similar to those found in animals in that the slopes for higher pulse rates were steeper than those for the lower pulse rates, consistent with a combined effect of multipulse integration and cumulative partial depolarization mechanisms at rates above 1000 pps. The maximum comfortable loudness level (C level) versus pulse rate functions were also examined to determine the effect of level on the slopes. Slopes of C-level functions were shallower than those for the T-level functions and were not correlated with those of the T-level functions, so the mechanisms underlying these two functions are probably not identical. The slopes of the T- or C-level functions were not dependent on stimulus-current level. Based on these results, we suggest that slopes of T level versus pulse rate functions might be a useful measure for estimating nerve survival in the cochlea in regions close to the stimulation sites., (Copyright © 2012 Elsevier B.V. All rights reserved.)

Published

2012

197. The effect of loudness on the reverberance of music: reverberance prediction using loudness models.

Author

Lee D, Cabrera D, and Martens WL

Subjects

Acoustic Stimulation methods, Analysis of Variance, Discrimination, Psychological physiology, Humans, Pressure, Acoustics, Loudness Perception physiology, Music

Abstract

This study examines the auditory attribute that describes the perceived amount of reverberation, known as "reverberance." Listening experiments were performed using two signals commonly heard in auditoria: excerpts of orchestral music and western classical singing. Listeners adjusted the decay rate of room impulse responses prior to convolution with these signals, so as to match the reverberance of each stimulus to that of a reference stimulus. The analysis examines the hypothesis that reverberance is related to the loudness decay rate of the underlying room impulse response. This hypothesis is tested using computational models of time varying or dynamic loudness, from which parameters analogous to conventional reverberation parameters (early decay time and reverberation time) are derived. The results show that listening level significantly affects reverberance, and that the loudness-based parameters outperform related conventional parameters. Results support the proposed relationship between reverberance and the computationally predicted loudness decay function of sound in rooms., (© 2012 Acoustical Society of America)

Published

2012

198. A psychophysical method for measuring spatial resolution in cochlear implants.

Author

Azadpour M and McKay CM

Subjects

Acoustic Stimulation methods, Aged, Discrimination, Psychological physiology, Female, Humans, Loudness Perception physiology, Male, Middle Aged, Cochlear Implantation methods, Psychoacoustics, Sound Localization physiology, Space Perception physiology, Speech Perception physiology

Abstract

A novel psychophysical method was developed for assessing spatial resolution in cochlear implants. Spectrally flat and spectrally peaked pulse train stimuli were generated by interleaving pulses on 11 electrodes. Spectrally flat stimuli used loudness-balanced currents and the spectrally peaked stimuli had a single spatial ripple with the current of the middle electrode raised to create a peak while the currents on two electrodes equally spaced at variable distance from the peak electrode were reduced to create valleys. The currents on peak and valley electrodes were adjusted to balance the overall loudness with the spectrally flat stimulus, while keeping the currents on flanking electrodes fixed. The psychometric functions obtained from percent correct discrimination of peaked and flat stimuli versus the distance between peak and valley electrodes were used to quantify spatial resolution for each of the eight subjects. The ability to resolve the spatial ripple correlated strongly with current level difference limens measured on the peak electrode. The results were consistent with a hypothesis that a factor other than spread of excitation (such as neural response variance) might underlie much of the variability in spatial resolution. Resolution ability was not correlated with phoneme recognition in quiet or sentence recognition in quiet and background noise, consistent with a hypothesis that implantees rely on cues other than fine spectral detail to identify speech, perhaps because this detail is poorly accessible or unreliable.

Published

2012

199. Reducing current spread using current focusing in cochlear implant users.

Author

Landsberger DM, Padilla M, and Srinivasan AG

Subjects

Acoustic Stimulation, Aged, Deafness physiopathology, Deafness therapy, Electric Stimulation, Electrophysiological Phenomena, Female, Humans, Loudness Perception physiology, Male, Middle Aged, Perceptual Masking physiology, Speech Perception physiology, Cochlear Implants

Abstract

Cochlear implant performance in difficult listening situations is limited by channel interactions. It is known that partial tripolar (PTP) stimulation reduces the spread of excitation (SOE). However, the greater the degree of current focusing, the greater the absolute current required to maintain a fixed loudness. As current increases, so does SOE. In experiment 1, the SOE for equally loud stimuli with different degrees of current focusing is measured via a forward-masking procedure. Results suggest that at a fixed loudness, some but not all patients have a reduced SOE with PTP stimulation. Therefore, it seems likely that a PTP speech processing strategy could improve spectral resolution for only those patients with a reduced SOE. In experiment 2, the ability to discriminate different levels of current focusing was measured. In experiment 3, patients subjectively scaled verbal descriptors of stimuli of various levels of current focusing. Both discrimination and scaling of verbal descriptors correlated well with SOE reduction, suggesting that either technique have the potential to be used clinically to quickly predict which patients would receive benefit from a current focusing strategy., (Copyright © 2012 Elsevier B.V. All rights reserved.)

Published

2012

200. Evidence of the enhancement effect in electrical stimulation via electrode matching (L).

Author

Goupell MJ and Mostardi MJ

Subjects

Adult, Aged, Analysis of Variance, Discrimination, Psychological, Electric Stimulation, Electrodes, Humans, Loudness Perception physiology, Middle Aged, Perceptual Masking physiology, Young Adult, Cochlear Implants, Pitch Discrimination physiology, Speech Perception physiology

Abstract

The ability to match a pulsing electrode during multi-electrode stimulation through a research interface was measured in seven cochlear-implant (CI) users. Five listeners were relatively good at the task and two could not perform the task. Performance did not vary as a function of the number of electrodes or stimulation level. Performance on the matching task was not correlated to performance on an electrode-discrimination task. The listeners may have experienced the auditory enhancement effect, and this may have implications for speech recognition in noise for CI users., (© 2012 Acoustical Society of America)

Published

2012