Abstract
During speech, how does the brain integrate information processed on different timescales and in separate brain areas so we can understand what is said? This is the language binding problem. Dynamic functional connectivity (brief periods of synchronization in the phase of EEG oscillations) may provide some answers. Here we investigate time and frequency characteristics of oscillatory power and phase synchrony (dynamic functional connectivity) during speech comprehension. Twenty adults listened to meaningful English sentences and non-sensical “Jabberwocky” sentences in which pseudo-words replaced all content words, while EEG was recorded. Results showed greater oscillatory power and global connectivity strength (mean phase lag index) in the gamma frequency range (30–80 Hz) for English compared to Jabberwocky. Increased power and connectivity relative to baseline was also seen in the theta frequency range (4–7 Hz), but was similar for English and Jabberwocky. High-frequency gamma oscillations may reflect a mechanism by which the brain transfers and integrates linguistic information so we can extract meaning and understand what is said. Slower frequency theta oscillations may support domain-general processing of the rhythmic features of speech. Our findings suggest that constructing a meaningful representation of speech involves dynamic interactions among distributed brain regions that communicate through frequency-specific functional networks.
Highlights
Specialty section: This article was submitted to Language Sciences, a section of the journal Frontiers in Psychology
Our findings suggest that constructing a meaningful representation of speech involves dynamic interactions among distributed brain regions that communicate through frequency-specific functional networks
The second notable effect was a large increase in global connectivity in theta (4–7 Hz) around 0.5–1 s after both English and Jaberwocky sentence onsets, with no significant differences between conditions
Summary
Specialty section: This article was submitted to Language Sciences, a section of the journal Frontiers in Psychology. We investigate time and frequency characteristics of oscillatory power and phase synchrony (dynamic functional connectivity) during speech comprehension. The goal of this study is to better understand the time and frequency characteristics of the functional networks that support meaningful spoken language processing in the brain. With time-frequency analysis of EEG oscillations, one can measure both changes in local brain activity and long-range communication among distributed brain regions during language processing. As measured through changes in cross-trial phase synchronization over time, has been used to investigate the brain networks supporting many aspects of sensory and cognitive processing (Rodriguez et al, 1999; Singer, 2007; Siegel et al, 2012; Fries, 2015). Without meaningful lexical-semantic content, both the memory retrieval and the binding stages of language comprehension that unify semantic with syntactic, and phonological information are disrupted (Hagoort, 2005)
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