Stimulus-aware spatial filtering for single-trial neural response and temporal response function estimation in high-density EEG with applications in auditory research

Das, Neetha; Vanthornhout, Jonas; Francart, Tom; Bertrand, Alexander

doi:10.1101/541318

Cited by 2 publications

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References 60 publications

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“…In the current study, we apply a data-driven method to remove non-stimulus-related activity from the EEG signals and automatically select the channels of interest, which is described in detail by Das, Vanthornhout, Francart, & Bertrand (2019). This method makes use of the Generalized Eigenvalue Decomposition GEVD (Hassani, Bertrand, & Moonen, 2016), which has been used to remove artefacts from the EEG (Somers, Francart, & Bertrand, 2018), and cancel EEG noise (Hajipour Sardouie, Shamsollahi, Albera, & Merlet, 2015;Serizel, Moonen, Van Dijk, & Wouters, 2014).…”

Section: Introductionmentioning

confidence: 99%

Data-driven spatial filtering for improved measurement of cortical tracking of multiple representations of speech

et al. 2019

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Objective -Measurement of the cortical tracking of continuous speech from electroencephalography (EEG) recordings using a forward model is an important tool in auditory neuroscience. Usually the stimulus is represented by its temporal envelope. Recently, the phonetic representation of speech was successfully introduced in English. We aim to show that the EEG prediction from phoneme-related speech features is possible in Dutch. The method requires a manual channel selection based on visual inspection or prior knowledge to obtain a summary measure of cortical tracking. We evaluate a method to (1) remove nonstimulus-related activity from the EEG signals to be predicted, and (2) automatically select the channels of interest. Approach -Eighteen participants listened to a Flemish story, while their EEG was recorded. Subject-specific and grand-average temporal response functions were determined between the EEG activity in different frequency bands and several stimulus features: the envelope, spectrogram, phonemes, phonetic features or a combination. The temporal response functions were used to predict EEG from the stimulus, and the predicted was compared with the recorded EEG, yielding a measure of cortical tracking of stimulus features. A spatial filter was calculated based on the generalized eigenvalue decomposition (GEVD), and the effect on EEG prediction accuracy was determined. Main results -A model including both low-and high-level speech representations was able to better predict the brain responses to the speech than a model only including low-level features. The inclusion of a GEVD-based spatial filter in the model increased the prediction accuracy of cortical responses to each speech feature at both single-subject (270% improvement) and group-level (310%). Significance -We showed that the inclusion of acoustical and phonetic speech information and the addition of a data-driven spatial filter allow improved modelling of the relationship between the speech and its brain responses and offer an automatic channel selection.

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confidence: 99%

Data-driven spatial filtering for improved measurement of cortical tracking of multiple representations of speech

et al. 2019

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Neural tracking as a diagnostic tool to assess the auditory pathway

Canneyt

Gillis

Vanthornhout

et al. 2021

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The neural tracking framework enables the analysis of neural responses (EEG) to continuous natural speech, e.g., a story or a podcast. This allows for objective investigation of a range of auditory and linguistic processes in the brain during natural speech perception. This approach is more ecologically valid than traditional auditory evoked responses and has great potential for both research and clinical applications. In this article, we review the neural tracking framework and highlight three prominent examples of neural tracking analyses. This includes the neural tracking of the fundamental frequency of the voice (f0), the speech envelope and linguistic features. Each of these analyses provides a unique point of view into the hierarchical stages of speech processing in the human brain. f0-tracking assesses the encoding of fine temporal information in the early stages of the auditory pathway, i.e. from the auditory periphery up to early processing in the primary auditory cortex. This fundamental processing in (mostly) subcortical stages forms the foundation of speech perception in the cortex. Envelope tracking reflects bottom-up and top-down speech-related processes in the auditory cortex, and is likely necessary but not sufficient for speech intelligibility. To study neural processes more directly related to speech intelligibility, neural tracking of linguistic features can be used. This analysis focuses on the encoding of linguistic features (e.g. word or phoneme surprisal) in the brain. Together these analyses form a multi-faceted and time-effective objective assessment of the auditory and linguistic processing of an individual.

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Stimulus-aware spatial filtering for single-trial neural response and temporal response function estimation in high-density EEG with applications in auditory research

Cited by 2 publications

References 60 publications

Data-driven spatial filtering for improved measurement of cortical tracking of multiple representations of speech

Data-driven spatial filtering for improved measurement of cortical tracking of multiple representations of speech

Neural tracking as a diagnostic tool to assess the auditory pathway

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