Incorporating models of subcortical processing improves the ability to predict EEG responses to natural speech

Lindboom, Elsa; Nidiffer, Aaron; Carney, Laurel H.; Lalor, Edmund C.

doi:10.1101/2023.01.02.522438

Cited by 2 publications

(1 citation statement)

References 67 publications

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“…However, a recent study has shown that predictors derived from a complex model of the auditory periphery [20] that incorporates non-linear stages can lead to improved subcortical TRFs [21]. Another recent study showed that auditory-model-derived predictors outperform previously used envelope predictors even for cortical TRFs [22].…”

Section: Introductionmentioning

confidence: 99%

Predictors for estimating subcortical EEG responses to continuous speech

Kulasingham

Bachmann

Eskelund

et al. 2023

Preprint

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Perception of sounds and speech involves structures in the auditory brainstem that rapidly process ongoing auditory stimuli. The role of these structures in speech understanding can be investigated by measuring their electrical activity using scalpmounted electrodes. Typical analysis methods involve averaging responses to many short repetitive stimuli. Recently, responses to more ecologically relevant continuous speech were detected using linear encoding models called temporal response functions (TRFs). Non-linear predictors derived from complex auditory models may improve TRFs. Here, we compare predictors from both simple and complex auditory models for estimating brainstem TRFs on electroencephalography (EEG) data from 24 subjects listening to continuous speech. Predictors from simple models result in comparable TRFs to those from complex models, and are much faster to compute. We also discuss the effect of data length on TRF peaks for efficient estimation of subcortical TRFs.

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Section: Introductionmentioning

confidence: 99%

Predictors for estimating subcortical EEG responses to continuous speech

Kulasingham

Bachmann

Eskelund

et al. 2023

Preprint

View full text Add to dashboard Cite

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Subcortical responses to music and speech are alike while cortical responses diverge

Shan,

Cappelloni,

Maddox

2024

Sci Rep

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Music and speech are encountered daily and are unique to human beings. Both are transformed by the auditory pathway from an initial acoustical encoding to higher level cognition. Studies of cortex have revealed distinct brain responses to music and speech, but differences may emerge in the cortex or may be inherited from different subcortical encoding. In the first part of this study, we derived the human auditory brainstem response (ABR), a measure of subcortical encoding, to recorded music and speech using two analysis methods. The first method, described previously and acoustically based, yielded very different ABRs between the two sound classes. The second method, however, developed here and based on a physiological model of the auditory periphery, gave highly correlated responses to music and speech. We determined the superiority of the second method through several metrics, suggesting there is no appreciable impact of stimulus class (i.e., music vs speech) on the way stimulus acoustics are encoded subcortically. In this study’s second part, we considered the cortex. Our new analysis method resulted in cortical music and speech responses becoming more similar but with remaining differences. The subcortical and cortical results taken together suggest that there is evidence for stimulus-class dependent processing of music and speech at the cortical but not subcortical level.

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Incorporating models of subcortical processing improves the ability to predict EEG responses to natural speech

Cited by 2 publications

References 67 publications

Predictors for estimating subcortical EEG responses to continuous speech

Predictors for estimating subcortical EEG responses to continuous speech

Subcortical responses to music and speech are alike while cortical responses diverge

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