Your search keyword '"binaural processing"' showing total 11 results

1. Lateralization of virtual sound sources with a binaural cochlear-implant sound coding strategy inspired by the medial olivocochlear reflex.

Author

Lopez-Poveda, Enrique A., Eustaquio-Martín, Almudena, Fumero, Milagros J., Stohl, Joshua S., Schatzer, Reinhold, Nopp, Peter, Wolford, Robert D., Gorospe, José M., Polo, Rubén, Revilla, Auxiliadora Gutiérrez, and Wilson, Blake S.

Subjects

*COCHLEAR implants, *REFLEXES, *ACOUSTIC localization, *ACOUSTICS

Abstract

Many users of bilateral cochlear implants (BiCIs) localize sound sources less accurately than do people with normal hearing. This may be partly due to using two independently functioning CIs with fixed compression, which distorts and/or reduces interaural level differences (ILDs). Here, we investigate the potential benefits of using binaurally coupled, dynamic compression inspired by the medial olivocochlear reflex; an approach termed "the MOC strategy" (Lopez-Poveda et al., 2016, Ear Hear 37:e138-e148). Twelve BiCI users were asked to localize wideband (125–6000 Hz) noise tokens in a virtual horizontal plane. Stimuli were processed through a standard (STD) sound processing strategy (i.e., involving two independently functioning sound processors with fixed compression) and three different implementations of the MOC strategy: one with fast (MOC1) and two with slower contralateral control of compression (MOC2 and MOC3). The MOC1 and MOC2 strategies had effectively greater inhibition in the higher than in the lower frequency channels, while the MOC3 strategy had slightly greater inhibition in the lower than in the higher frequency channels. Localization was most accurate with the MOC1 strategy, presumably because it provided the largest and less ambiguous ILDs. The angle error improved slightly from 25.3° with the STD strategy to 22.7° with the MOC1 strategy. The improvement in localization ability over the STD strategy disappeared when the contralateral control of compression was made slower, presumably because stimuli were too short (200 ms) for the slower contralateral inhibition to enhance ILDs. Results suggest that some MOC implementations hold promise for improving not only speech-in-noise intelligibility, as shown elsewhere, but also sound source lateralization. • Sound lateralization for bilateral cochlear-implant users was tested using virtual acoustics. • Binaural sound coding inspired by the medial olivocochlear reflex can enhance inter-aural level differences. • The use of binaurally coupled compression can improve sound lateralization. [ABSTRACT FROM AUTHOR]

Published

2019

2. A framework for testing and comparing binaural models.

Author

Dietz, Mathias, Lestang, Jean-Hugues, Majdak, Piotr, Stern, Richard M., Marquardt, Torsten, Ewert, Stephan D., Hartmann, William M., and Goodman, Dan F.M.

Subjects

*AUDITORY perception, *MATHEMATICAL models, *HEARING, *OPERATIONS research, *MEDICAL sciences

Abstract

Auditory research has a rich history of combining experimental evidence with computational simulations of auditory processing in order to deepen our theoretical understanding of how sound is processed in the ears and in the brain. Despite significant progress in the amount of detail and breadth covered by auditory models, for many components of the auditory pathway there are still different model approaches that are often not equivalent but rather in conflict with each other. Similarly, some experimental studies yield conflicting results which has led to controversies. This can be best resolved by a systematic comparison of multiple experimental data sets and model approaches. Binaural processing is a prominent example of how the development of quantitative theories can advance our understanding of the phenomena, but there remain several unresolved questions for which competing model approaches exist. This article discusses a number of current unresolved or disputed issues in binaural modelling, as well as some of the significant challenges in comparing binaural models with each other and with the experimental data. We introduce an auditory model framework, which we believe can become a useful infrastructure for resolving some of the current controversies. It operates models over the same paradigms that are used experimentally. The core of the proposed framework is an interface that connects three components irrespective of their underlying programming language: The experiment software, an auditory pathway model, and task-dependent decision stages called artificial observers that provide the same output format as the test subject. [ABSTRACT FROM AUTHOR]

Published

2018

3. Intelligibility in speech maskers with a binaural cochlear implant sound coding strategy inspired by the contralateral medial olivocochlear reflex.

Author

Lopez-Poveda, Enrique A., Eustaquio-Martín, Almudena, Stohl, Joshua S., Wolford, Robert D., Schatzer, Reinhold, Gorospe, José M., Ruiz, Santiago Santa Cruz, Benito, Fernando, and Wilson, Blake S.

Subjects

*COCHLEAR implants, *BINAURAL hearing aids, *SPEECH perception, *INTELLIGIBILITY of speech, *DEAFNESS

Abstract

We have recently proposed a binaural cochlear implant (CI) sound processing strategy inspired by the contralateral medial olivocochlear reflex (the MOC strategy) and shown that it improves intelligibility in steady-state noise (Lopez-Poveda et al., 2016, Ear Hear 37:e138-e148). The aim here was to evaluate possible speech-reception benefits of the MOC strategy for speech maskers, a more natural type of interferer. Speech reception thresholds (SRTs) were measured in six bilateral and two single-sided deaf CI users with the MOC strategy and with a standard (STD) strategy. SRTs were measured in unilateral and bilateral listening conditions, and for target and masker stimuli located at azimuthal angles of (0°, 0°), (−15°, +15°), and (−90°, +90°). Mean SRTs were 2–5 dB better with the MOC than with the STD strategy for spatially separated target and masker sources. For bilateral CI users, the MOC strategy (1) facilitated the intelligibility of speech in competition with spatially separated speech maskers in both unilateral and bilateral listening conditions; and (2) led to an overall improvement in spatial release from masking in the two listening conditions. Insofar as speech is a more natural type of interferer than steady-state noise, the present results suggest that the MOC strategy holds potential for promising outcomes for CI users. [ABSTRACT FROM AUTHOR]

Published

2017

4. Effects of hearing loss and age on the binaural processing of temporal envelope and temporal fine structure information

Author

Brian C. J. Moore

Subjects

0301 basic medicine, Sound localization, medicine.medical_specialty, Computer science, Hearing loss, genetic processes, Audiology, Deafness, Phase locking, 03 medical and health sciences, 0302 clinical medicine, otorhinolaryngologic diseases, medicine, natural sciences, Hearing Loss, Cochlea, Binaural processing, fungi, Sensory Systems, 030104 developmental biology, Auditory Perception, Speech Perception, medicine.symptom, 030217 neurology & neurosurgery, Envelope (motion)

Abstract

Within the cochlea, broadband sounds like speech and music are filtered into a series of narrowband signals, each with a relatively slowly varying envelope (ENV) imposed on a rapidly oscillating carrier (the temporal fine structure, TFS). Information about ENV is conveyed by the timing and short-term rate of action potentials in the auditory nerve while information about TFS is conveyed by synchronization of action potentials to a specific phase of the waveform in the cochlea (phase locking). This paper describes the effects of age and hearing loss on the binaural processing of ENV and TFS information, i.e. on the processing of differences in ENV and TFS at the two ears. The binaural processing of TFS information is adversely affected by both hearing loss and increasing age. The binaural processing of ENV information deteriorates somewhat with increasing age but is only slightly affected by hearing loss. The reduced TFS processing abilities found for older/hearing-impaired subjects may partially account for the difficulties that such subjects experience in complex listening situations when the target speech and interfering sounds come from different directions in space.

Published

2020

5. A framework for testing and comparing binaural models

Author

William M. Hartmann, Mathias Dietz, Piotr Majdak, Jean-Hugues Lestang, Richard M. Stern, Dan F. M. Goodman, Torsten Marquardt, and Stephan D. Ewert

Subjects

0301 basic medicine, Auditory Pathways, Time Factors, Interface (Java), Computer science, Models, Psychological, Test subject, Reproducible research, 03 medical and health sciences, 0302 clinical medicine, Software, Hearing, Humans, Sound Localization, Psychoacoustics, Interaural time differences, Binaural processing, Cognitive science, Auditory models, business.industry, Speech Intelligibility, Experimental data, 1103 Clinical Sciences, Sensory Systems, 030104 developmental biology, Acoustic Stimulation, Otorhinolaryngology, 1116 Medical Physiology, Auditory Perception, Speech Perception, Cues, 1109 Neurosciences, business, Binaural recording, 030217 neurology & neurosurgery

Abstract

Auditory research has a rich history of combining experimental evidence with computational simulations of auditory processing in order to deepen our theoretical understanding of how sound is processed in the ears and in the brain. Despite significant progress in the amount of detail and breadth covered by auditory models, for many components of the auditory pathway there are still different model approaches that are often not equivalent but rather in conflict with each other. Similarly, some experimental studies yield conflicting results which has led to controversies. This can be best resolved by a systematic comparison of multiple experimental data sets and model approaches. Binaural processing is a prominent example of how the development of quantitative theories can advance our understanding of the phenomena, but there remain several unresolved questions for which competing model approaches exist. This article discusses a number of current unresolved or disputed issues in binaural modelling, as well as some of the significant challenges in comparing binaural models with each other and with the experimental data. We introduce an auditory model framework, which we believe can become a useful infrastructure for resolving some of the current controversies. It operates models over the same paradigms that are used experimentally. The core of the proposed framework is an interface that connects three components irrespective of their underlying programming language: The experiment software, an auditory pathway model, and task-dependent decision stages called artificial observers that provide the same output format as the test subject.

Published

2018

6. Time–intensity trading in bilateral congenital aural atresia patients

Author

Schmerber, Sébastien, Sheykholeslami, Kianoush, Kermany, Mohammad Habiby, Hotta, Shoko, and Kaga, Kimitaka

Subjects

*BILIARY atresia, *PATIENTS, *HEARING aids, *AUDIOLOGY

Abstract

Abstract: In an effort to examine the rules by which information of bilaterally applied bone-conducted signals arising from interaural time differences (ITD) and interaural intensity differences (IID) is combined, data were measured for continuous 500 Hz narrow band noise at 65–70 dB HL in 11 patients with bilateral congenital aural atresia. Time–intensity trading functions were obtained by shifting the sound image towards one side using ITD, and shifting back to a centered sound image by varying the IID in the same ear (auditory midline task). ITD values were varied from −600 to +600 μs at 200 μs steps, where negative values indicate delays to the right ear. The results indicate that time–intensity trading is present in patients with bilateral aural atresia. The gross response properties of time–intensity trading in response to bone-conducted signals were comparable in patients with bilateral aural atresia and normal-hearing subjects, though there was a larger inter-subject variability and higher discrimination thresholds across IIDs in the atresia group. These results suggest that the mature auditory brainstem has a potential to employ binaural cues later in life, although to a restricted degree. A binaural fitting of a bone-conducted hearing aid might optimize binaural hearing and improve sound lateralization, and we recommend now systematically bilateral fitting in aural atresia patients. [Copyright &y& Elsevier]

Published

2005

7. Sound localization latency in normal hearing and simulated unilateral hearing loss

Author

Erik Berninger, Martin Eklöf, and Filip Asp

Subjects

0301 basic medicine, Sound localization, Adult, medicine.medical_specialty, Adolescent, Stimulus (physiology), Audiology, Hearing Loss, Unilateral, 03 medical and health sciences, Young Adult, 0302 clinical medicine, Hearing, medicine, Humans, Sound Localization, Mathematics, Binaural processing, Hearing Tests, Repeated measures design, Sigmoid function, medicine.disease, Gaze, Sensory Systems, 030104 developmental biology, Auditory Perception, Unilateral hearing loss, Binaural recording, 030217 neurology & neurosurgery

Abstract

Directing gaze towards auditory events is a natural behavior. In addition to the well-known accuracy of auditory elicited gaze responses for normal binaural listening, their latency is a measure of possible clinical interest and methodological importance. The aim was to develop a clinically feasible method to assess sound localization latency (SLL), and to study SLL as a function of simulated unilateral hearing loss (SUHL) and the relationship with accuracy. Eight healthy and normal-hearing adults (18–40 years) participated in this study. Horizontal gaze responses, recorded by non-invasive corneal reflection eye-tracking, were obtained during azimuthal shifts (24 trials) of a 3-min continuous auditory stimulus. In each trial, a sigmoid function was fitted to gaze samples. Latency was estimated by the abscissa corresponding to 50% of the arctangent amplitude. SLL was defined as the mean latency across trials. SLL was measured in normal-hearing and simulated SUHL conditions (SUHL30 and SUHL43: mean threshold of 30 dB HL and 43 dB HL across 0.5, 1, 2, and 4 kHz). In the normal-hearing condition, the mean ± SD SLL was 280 ± 40 ms (n = 8) with a test-retest SD = 20 ms. A linear mixed model showed a statistically significant effect of listening condition on SLL. The SUHL30 and SUHL43 conditions revealed a mean SLL of 370 ± 49 ms and 540 ± 120 ms, respectively. Repeated measures correlation analysis showed a clear relationship between SLL and the average sound localization accuracy (R2 = 0.94). The rapid and reliable method to obtain SLL may be an important clinical tool for evaluation of binaural processing. Future studies in clinical cohorts are needed to assess whether SLL may reveal information about binaural processing abilities beyond that afforded by sound localization accuracy.

Published

2019

8. Different binaural processing of the envelope component and the temporal fine structure component of a narrowband noise in rat inferior colliculus.

Author

Xu, Na, Luo, Lu, Chen, Liangjie, Ding, Yu, and Li, Liang

Subjects

*INFERIOR colliculus, *LABORATORY rats, *AUDITORY perception, *RATS, *NOISE, *MESENCEPHALON

Abstract

l Binaural processing of envelope (ENV) and temporal fine structure (TFS) information was examined by frequency-following responses (FFRs) in rat ICC. l Binaural FFR ENV received a predominant contribution from contralateral inputs while inhibited by ipsilateral inputs, showing a binaural inhibition property. l Binaural FFR TFS was excited by the inputs from both sides, showing a binaural summation property. l Results suggested distinct binaural integration mechanisms for ENV and TFS information. Complex broadband sounds are decomposed by peripheral auditory filters into a series of relatively narrowband signals, each with a slowly varying envelope (ENV) and a rapidly fluctuating temporal fine structure (TFS). ENV and TFS information at the bilateral ears contribute differentially to auditory perception. However, whether the difference could attribute to mechanisms of binaural integration remains an open question. As a potential neural correlate, subsets of neurons in the central nucleus of the inferior colliculus (ICC) are known to integrate binaural information with binaural inhibition or binaural summation. Therefore, we recorded the frequency-following responses (FFRs) to the ENV and TFS components of narrowband noises in the ICC of anesthetized rats and examined changes in FFR amplitude and stimulus-response coherence under various sound-delivery settings. We showed that binaural FFR ENV was predominantly elicited by contralateral inputs and inhibited by ipsilateral inputs, exhibiting a "binaural-inhibition" like property. On the other hand, binaural FFR TFS received a balanced contribution from both sides, echoing the "binaural-summation" mechanism. What is more, binaural FFR ENV was significantly correlated with contralateral-evoked but not ipsilateral-evoked FFR ENV , while binaural FFR TFS correlated with both contralateral- and ipsilateral-evoked FFR TFS. Overall, these results suggest distinct binaural processing of ENV and TFS information at the midbrain level. [ABSTRACT FROM AUTHOR]

Published

2021

9. Effects of hearing loss and age on the binaural processing of temporal envelope and temporal fine structure information.

Author

Moore, Brian C.J.

Subjects

*HEARING disorders, *INTERAURAL time difference, *ACOUSTIC nerve

Abstract

Within the cochlea, broadband sounds like speech and music are filtered into a series of narrowband signals, each with a relatively slowly varying envelope (ENV) imposed on a rapidly oscillating carrier (the temporal fine structure, TFS). Information about ENV is conveyed by the timing and short-term rate of action potentials in the auditory nerve while information about TFS is conveyed by synchronization of action potentials to a specific phase of the waveform in the cochlea (phase locking). This paper describes the effects of age and hearing loss on the binaural processing of ENV and TFS information, i.e. on the processing of differences in ENV and TFS at the two ears. The binaural processing of TFS information is adversely affected by both hearing loss and increasing age. The binaural processing of ENV information deteriorates somewhat with increasing age but is only slightly affected by hearing loss. The reduced TFS processing abilities found for older/hearing-impaired subjects may partially account for the difficulties that such subjects experience in complex listening situations when the target speech and interfering sounds come from different directions in space. • The binaural processing of envelope (ENV) and temporal fine structure (TFS) is reviewed. • Hearing loss and greater age adversely affect the processing of interaural time differences in TFS. • Hearing loss and greater age only slightly affect the processing of interaural time differences in ENV. • Hearing loss and greater age are associated with reduced masking level differences. • Hearing loss and greater age are associated with reduced spatial release from masking. [ABSTRACT FROM AUTHOR]

Published

2021

10. Point-neuron model for binaural interaction in MSO

Author

H. Steven Colburn and Yanan Han

Subjects

Neurons, Membrane potential, Physics, Binaural processing, Cell Membrane, Models, Neurological, Auditory Threshold, Biological neuron model, Olivary Nucleus, Inhibitory postsynaptic potential, Sensory Systems, Membrane Potentials, Electrophysiology, Acoustic Stimulation, nervous system, Ionic conductance, Auditory Perception, Medial superior olive, Neuroscience, Binaural recording

Abstract

A point-neuron model for the activity of individual cells in the medial superior olive (MSO) is described and shown to generate discharge patterns consistent with the activity of real neurons as reported in response to low-frequency sinusoidal stimulation. Inputs to the model cell are specified as primarylike firing patterns, and the cell membrane characteristics are specified in terms of constant-potential sources and time-varying conductances. Some conductances are determined in response to the input firings and some in response to output firing times, which are generated when the membrane potential of the model cell crosses threshold. Output firing patterns generated by the model cells are consistent with those reported from neurons in dog and cat MSO. These patterns are also compatible with those of the functionally specified coincidence model described in Colburn et al. (1990). Given these observations, the following questions are addressed: What parameter values in the point-neuron model are required to generate output patterns like those observed? How do these values compare to those expected or estimated from intracellular measurements in brainstem neurons? How might one reconcile the fact that inhibitory inputs are not necessary in the model for the generation of the observed firing patterns with the fact that MSO cells receive numerous inhibitory inputs?

Published

1993

11. Phase-locked responses to pure tones in the primary auditory cortex

Author

Mark N. Wallace, Trevor M. Shackleton, and Alan R. Palmer

Subjects

Auditory Cortex, Male, medicine.medical_specialty, Binaural processing, Acoustics, Guinea Pigs, Fundamental frequency, Audiology, Stimulus (physiology), Auditory cortex, Sensory Systems, Electrophysiology, Acoustic Stimulation, medicine, Auditory Perception, Evoked Potentials, Auditory, Animals, Female, Vocalization, Animal, Neural coding, Psychology, Temporal information, Coincidence detection in neurobiology

Abstract

At the level of the brainstem, precise temporal information is essential for some aspects of binaural processing, while at the level of the cortex, rate and place mechanisms for neural coding seem to predominate. However, we now show that precise timing of steady-state responses to pure tones occurs in the primary auditory cortex (AI). Recordings were made from 163 multi-units in guinea pig AI. All units increased their firing rate in response to pure tones at 100 Hz and 46 (28%) gave sustained responses which were synchronised with the stimulus waveform (phase-locking). The phase-locking units were clustered together in columns. Phase-locking was generally strongest in layers III and IV but was also recorded in layers I, II and V. Good phase-locking was observed over a range of 60-250 Hz: some units (30%) were narrow band while others (37%) were low-pass (33% were not determined). Phase-locking strength was also influenced by sound level: some units showed monotonic increases in strength with level and others were non-monotonic. Ten of the units provided a good temporal representation of the fundamental frequency (270 Hz) of a guinea pig vocalisation (rumble) and may be involved in analysing communication calls.

Published

2002