Atypical neural synchronization to speech envelope modulations in dyslexia

HIGHLIGHTSAuditory steady‐state responses measure synchronization of neural oscillations in the auditory cortices.Specific oscillatory bands are addressed using different speech envelope modulations.Dyslexic readers show reduced alpha synchronization to syllabic rates (10 Hz).Dyslexic readers show enhanced beta synchronization to phonemic rates (20 Hz).Bottom‐up and top‐down neural processes relate auditory synchronization to reading and phonology. ABSTRACT A fundamental deficit in the synchronization of neural oscillations to temporal information in speech could underlie phonological processing problems in dyslexia. In this study, the hypothesis of a neural synchronization impairment is investigated more specifically as a function of different neural oscillatory bands and temporal information rates in speech. Auditory steady‐state responses to 4, 10, 20 and 40 Hz modulations were recorded in normal reading and dyslexic adolescents to measure neural synchronization of theta, alpha, beta and low‐gamma oscillations to syllabic and phonemic rate information. In comparison to normal readers, dyslexic readers showed reduced non‐synchronized theta activity, reduced synchronized alpha activity and enhanced synchronized beta activity. Positive correlations between alpha synchronization and phonological skills were found in normal readers, but were absent in dyslexic readers. In contrast, dyslexic readers exhibited positive correlations between beta synchronization and phonological skills. Together, these results suggest that auditory neural synchronization of alpha and beta oscillations is atypical in dyslexia, indicating deviant neural processing of both syllabic and phonemic rate information. Impaired synchronization of alpha oscillations in particular demonstrated to be the most prominent neural anomaly possibly hampering speech and phonological processing in dyslexic readers.

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