Speech‐in‐noise understanding in older age: The role of inhibitory cortical responses

Roß, Bernhard; Dobri, Simon; Schumann, Annette

doi:10.1111/ejn.14573

Cited by 13 publications

(7 citation statements)

References 105 publications

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“…These results suggest a greater reliance on visual cues during speech perception, which complements the above findings that V1/V2 is employed in CI users during auditory-only listening. Reductions in auditory-evoked gamma responses as a consequence of an altered E/I ratio have also been shown in individuals with hearing loss and are correlated with reduced response suppression and impaired speech-in-noise performance compared with individuals with normal hearing (Ross et al 2020).…”

Section: Sensorineural Hearing Loss and Cochlear Implant Usersmentioning

confidence: 93%

Visual Influences on Auditory Behavioral, Neural, and Perceptual Processes: A Review

Opoku-Baah

Schoenhaut

Vassall

et al. 2021

JARO

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In a naturalistic environment, auditory cues are often accompanied by information from other senses, which can be redundant with or complementary to the auditory information. Although the multisensory interactions derived from this combination of information and that shape auditory function are seen across all sensory modalities, our greatest body of knowledge to date centers on how vision influences audition. In this review, we attempt to capture the state of our understanding at this point in time regarding this topic. Following a general introduction, the review is divided into 5 sections. In the first section, we review the psychophysical evidence in humans regarding vision’s influence in audition, making the distinction between vision’s ability to enhance versus alter auditory performance and perception. Three examples are then described that serve to highlight vision’s ability to modulate auditory processes: spatial ventriloquism, cross-modal dynamic capture, and the McGurk effect. The final part of this section discusses models that have been built based on available psychophysical data and that seek to provide greater mechanistic insights into how vision can impact audition. The second section reviews the extant neuroimaging and far-field imaging work on this topic, with a strong emphasis on the roles of feedforward and feedback processes, on imaging insights into the causal nature of audiovisual interactions, and on the limitations of current imaging-based approaches. These limitations point to a greater need for machine-learning-based decoding approaches toward understanding how auditory representations are shaped by vision. The third section reviews the wealth of neuroanatomical and neurophysiological data from animal models that highlights audiovisual interactions at the neuronal and circuit level in both subcortical and cortical structures. It also speaks to the functional significance of audiovisual interactions for two critically important facets of auditory perception—scene analysis and communication. The fourth section presents current evidence for alterations in audiovisual processes in three clinical conditions: autism, schizophrenia, and sensorineural hearing loss. These changes in audiovisual interactions are postulated to have cascading effects on higher-order domains of dysfunction in these conditions. The final section highlights ongoing work seeking to leverage our knowledge of audiovisual interactions to develop better remediation approaches to these sensory-based disorders, founded in concepts of perceptual plasticity in which vision has been shown to have the capacity to facilitate auditory learning.

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Section: Sensorineural Hearing Loss and Cochlear Implant Usersmentioning

confidence: 93%

Visual Influences on Auditory Behavioral, Neural, and Perceptual Processes: A Review

Opoku-Baah

Schoenhaut

Vassall

et al. 2021

JARO

View full text Add to dashboard Cite

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“…Understanding speech in noise (SIN) is a complex skill that is subject to a fairly large age-related decline (Anderson et al, 2011). This loss is not merely attributable to a degradation of structures of the auditory periphery; more and more central and cognitive domains are shown to contribute to SIN (Nahum et al, 2008;Parbery-Clark et al, 2009;Wong et al, 2009;Strait and Kraus, 2011;Moore et al, 2014;Ross et al, 2020). A fundamental mechanism for perceiving SIN involves the transformation of a complex acoustic environment into the representation of diverse auditory objects.…”

Section: Introductionmentioning

confidence: 99%

“…Beside the utilization of low-level information and bottom-up processing, effective top-down control of early auditory stages can be assumed as well, exerted via, for example, corticofugal pathways and the medial olivocochlear bundle (de Boer and Thornton, 2008;de Boer et al, 2012). Thus, stream segregation could be mediated by cognitive processes such as working memory (Parbery-Clark et al, 2009, 2011, inhibition (Ross et al, 2020), and attention (Wong et al, 2009;Strait and Kraus, 2011;Zendel et al, 2019), which seem to be conducive to SIN. In addition, it seems likely, that the implication of cognitive functions becomes particularly important with increasing age (Zendel and Alain, 2013).…”

Section: Introductionmentioning

confidence: 99%

Improved Speech in Noise Perception in the Elderly After 6 Months of Musical Instruction

et al. 2021

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Understanding speech in background noise poses a challenge in daily communication, which is a particular problem among the elderly. Although musical expertise has often been suggested to be a contributor to speech intelligibility, the associations are mostly correlative. In the present multisite study conducted in Germany and Switzerland, 156 healthy, normal-hearing elderly were randomly assigned to either piano playing or music listening/musical culture groups. The speech reception threshold was assessed using the International Matrix Test before and after a 6 month intervention. Bayesian multilevel modeling revealed an improvement of both groups over time under binaural conditions. Additionally, the speech reception threshold of the piano group decreased during stimuli presentation to the left ear. A right ear improvement only occurred in the German piano group. Furthermore, improvements were predominantly found in women. These findings are discussed in the light of current neuroscientific theories on hemispheric lateralization and biological sex differences. The study indicates a positive transfer from musical training to speech processing, probably supported by the enhancement of auditory processing and improvement of general cognitive functions.

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“…In previous studies, both types of response showed suppression in a paired stimulus paradigm, and therefore, both have been associated with sensory gating [30][31][32]. However, P1 and gamma activity exist in parallel and show different functional dependencies with age, hearing loss, and speech-in-noise understanding [56]. Additionally, the second onset after a 15 ms gap in the stimulus did not elicit a gamma activity, which is different from the P1.…”

Section: Evoked Gamma-band Responsesmentioning

confidence: 80%

Binaural Background Noise Enhances Neuromagnetic Responses from Auditory Cortex

2021

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The presence of binaural low-level background noise has been shown to enhance the transient evoked N1 response at about 100 ms after sound onset. This increase in N1 amplitude is thought to reflect noise-mediated efferent feedback facilitation from the auditory cortex to lower auditory centers. To test this hypothesis, we recorded auditory-evoked fields using magnetoencephalography while participants were presented with binaural harmonic complex tones embedded in binaural or monaural background noise at signal-to-noise ratios of 25 dB (low noise) or 5 dB (higher noise). Half of the stimuli contained a gap in the middle of the sound. The source activities were measured in bilateral auditory cortices. The onset and gap N1 response increased with low binaural noise, but high binaural and low monaural noise did not affect the N1 amplitudes. P1 and P2 onset and gap responses were consistently attenuated by background noise, and noise level and binaural/monaural presentation showed distinct effects. Moreover, the evoked gamma synchronization was also reduced by background noise, and it showed a lateralized reduction for monaural noise. The effects of noise on the N1 amplitude follow a bell-shaped characteristic that could reflect an optimal representation of acoustic information for transient events embedded in noise.

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Speech‐in‐noise understanding in older age: The role of inhibitory cortical responses

Cited by 13 publications

References 105 publications

Visual Influences on Auditory Behavioral, Neural, and Perceptual Processes: A Review

Visual Influences on Auditory Behavioral, Neural, and Perceptual Processes: A Review

Improved Speech in Noise Perception in the Elderly After 6 Months of Musical Instruction

Binaural Background Noise Enhances Neuromagnetic Responses from Auditory Cortex

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