Modelling firing regularity in the ventral cochlear nucleus: Mechanisms, and effects of stimulus level and synaptopathy

Goodman, Dan F. M.; Winter, Ian M.; Léger, Agnès C.; Cheveigné, Alain de; Lorenzi, Christian

doi:10.1016/j.heares.2017.09.010

Cited by 7 publications

(10 citation statements)

References 73 publications

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“…More generally, the effects of age and/or hearing loss modelled here by increases in internal noise (in the E and TFS paths) may correspond to increased spontaneous activity in auditory neurons (Palombi & Caspary, ; Wang et al ., ), increased firing irregularity (Goodman et al ., ), and changes in receptive fields due to the excitatory/inhibitory imbalance (Rajan, ; Scholl & Wehr, ). This excitatory/inhibitory imbalance may, in turn, impair the decoding of both E and/or TFS cues, which may partly depend on precise inhibition between neurons of adjacent frequencies (Shamma, ; Brand et al ., ; Gleich et al ., ; however, see Franken et al ., ).…”

Section: Discussionmentioning

confidence: 99%

“…following acoustic trauma, Kale & Heinz, 2010), the TFS information at higher stages of the auditory system (e.g. cochlear nucleus, inferior colliculus) might be 'noisier' due to a reduced number of inputs (Goodman et al, 2017). Noisier TFS representation would thus lead to poorer monaural TFS sensitivity, which would in turn impact binaural TFS processing.…”

Section: Behavioural Datamentioning

confidence: 99%

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A two‐path model of auditory modulation detection using temporal fine structure and envelope cues

Ewert

Paraouty

Lorenzi

2018

Eur J of Neuroscience

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A model using temporal-envelope cues was previously developed to explain perceptual interference effects between amplitude modulation and frequency modulation (FM). As that model could not accurately predict FM sensitivity and the interference effects, temporal fine structure (TFS) cues were added to the model. Thus, following the initial stage of the model consisting of a linear filter bank simulating cochlear filtering, processing was split into an 'envelope path' based on envelope power cues and a 'TFS path' based on a measure of the distribution of time intervals between successive zero-crossings. This yielded independent detectability indices for envelope and TFS cues, which were optimally combined to produce a single decision statistic. Independent internal noises in the envelope and TFS paths were adjusted to match the data. Simulations indicate that TFS cues are required to account for FM data for young normal-hearing listeners and that TFS processing is impaired for both older normal-hearing and hearing-impaired listeners. The role of TFS was further assessed by relating the monaural FM sensitivity to measures of interaural phase difference, commonly assumed to rely on binaural TFS sensitivity. The model demonstrates that binaural TFS sensitivity is considerably lower than monaural TFS sensitivity. Similar to FM thresholds, interaural phase difference sensitivity declined with age and hearing loss, although higher degradations were observed in binaural temporal processing compared to monaural processing. Overall, this model provides a novel tool to explore the mechanisms involved in FM processing in the normal auditory system and the degradations in FM sensitivity with ageing and hearing loss.

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Section: Discussionmentioning

confidence: 99%

Section: Behavioural Datamentioning

confidence: 99%

A two‐path model of auditory modulation detection using temporal fine structure and envelope cues

Ewert

Paraouty

Lorenzi

2018

Eur J of Neuroscience

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“…The ability to use temporal-envelope cues may be reduced in the impaired auditory system because of (1) reduced conversion of FM into temporal-envelope cues at the outputs of the cochlear filters, resulting from the loss of outer hair cells in the cochlea and the consequent broadening of the filters (Glasberg and Moore, 1986); (2) loss of auditory-nerve fibers (Kujawa and Liberman, 2009) and the consequent impoverished (i.e., more noisy) neural representation of temporal-envelope cues in the early auditory system, as suggested by the psychophysical, electrophysiological and modeling work of Bharadwaj et al (2015), Goodman et al (2017), and Paul et al (2017); (3) central changes, such as a loss of inhibition, which may affect envelope extraction and processing (Davis et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

Sensorineural hearing loss impairs sensitivity but spares temporal integration for detection of frequency modulation

Wallaert

Varnet

Moore

et al. 2018

The Journal of the Acoustical Society of America

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The effect of the number of modulation cycles () on frequency-modulation (FM) detection thresholds (FMDTs) was measured with and without interfering amplitude modulation (AM) for hearing-impaired (HI) listeners, using a 500-Hz sinusoidal carrier and FM rates of 2 and 20 Hz. The data were compared with FMDTs for normal-hearing (NH) listeners and AM detection thresholds (AMDTs) for NH and HI listeners [Wallaert, Moore, and Lorenzi (2016). J. Acoust. Soc. , 3088-3096; Wallaert, Moore, Ewert, and Lorenzi (2017). J. Acoust. Soc., 971-980]. FMDTs were higher for HI than for NH listeners, but the effect of increasing was similar across groups. In contrast, AMDTs were lower and the effect of increasing was greater for HI listeners than for NH listeners. A model of temporal-envelope processing based on a modulation filter-bank and a template-matching decision strategy accounted better for the FMDTs at 20 Hz than at 2 Hz for young NH listeners and predicted greater temporal integration of FM than observed for all groups. These results suggest that different mechanisms underlie AM and FM detection at low rates and that hearing loss impairs FM-detection mechanisms, but preserves the memory and decision processes responsible for temporal integration of FM.

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“…In Population mechanisms, we investigate these population level effects with a lateral inhibition mechanism. Throughout, we use abstract rate models of neurons with rich dynamics to extract the essential details while keeping the model complexity manageable (similarly to Goodman et al 2017). This enables us to investigate how the behaviour of the model depends on all of the parameters and plot the parameter spaces, which would not be possible with a biophysically detailed model with a large number of parameters.…”

Section: Resultsmentioning

confidence: 99%

“…We therefore strongly encourage researchers to investigate the extent to which new experimental results can be reproduced using simple and general models, and thoroughly explore the parameter space in detail along the lines suggested by O'Leary et al (2015) and used previously in the auditory system in Goodman et al (2017).…”

Section: Discussionmentioning

confidence: 96%

General neural mechanisms can account for rising slope preference in localization of ambiguous sounds

Lestang

Goodman

2019

Preprint

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Sound localization in reverberant environments is a difficult task that human listeners perform effortlessly. Many neural mechanisms have been proposed to account for this behavior. Generally they rely on emphasizing localization information at the onset of the incoming sound while discarding localization cues that arrive later. We modelled several of these mechanisms using neural circuits commonly found in the brain and tested their performance in the context of experiments showing that, in the dominant frequency region for sound localisation, we have a preference for auditory cues arriving during the rising slope of the sound energy (Dietz et al., 2013). We found that both single cell mechanisms (onset and adaptation) and population mechanisms (lateral inhibition) were easily able to reproduce the results across a very wide range of parameter settings. This suggests that sound localization in reverberant environments may not require specialised mechanisms specific to that task, but may instead rely on common neural circuits in the brain. This is in line with the theory that the brain consists of functionally overlapping general purpose mechanisms rather than a collection of mechanisms each highly specialised to specific tasks. This research is fully reproducible, and we made our code available to edit and run online via interactive live notebooks.

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Modelling firing regularity in the ventral cochlear nucleus: Mechanisms, and effects of stimulus level and synaptopathy

Cited by 7 publications

References 73 publications

A two‐path model of auditory modulation detection using temporal fine structure and envelope cues

A two‐path model of auditory modulation detection using temporal fine structure and envelope cues

Sensorineural hearing loss impairs sensitivity but spares temporal integration for detection of frequency modulation

General neural mechanisms can account for rising slope preference in localization of ambiguous sounds

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