Abstract
Acoustic speech output results from coordinated articulation of dozens of muscles, bones and cartilages of the vocal mechanism. While we commonly take the fluency and speed of our speech productions for granted, the neural mechanisms facilitating the requisite muscular control are not completely understood. Previous neuroimaging and electrophysiology studies of speech sensorimotor control has typically concentrated on speech sounds (i.e., phonemes, syllables and words) in isolation; sentence-length investigations have largely been used to inform coincident linguistic processing. In this study, we examined the neural representations of segmental features (place and manner of articulation, and voicing status) in the context of fluent, continuous speech production. We used recordings from the cortical surface [electrocorticography (ECoG)] to simultaneously evaluate the spatial topography and temporal dynamics of the neural correlates of speech articulation that may mediate the generation of hypothesized gestural or articulatory scores. We found that the representation of place of articulation involved broad networks of brain regions during all phases of speech production: preparation, execution and monitoring. In contrast, manner of articulation and voicing status were dominated by auditory cortical responses after speech had been initiated. These results provide a new insight into the articulatory and auditory processes underlying speech production in terms of their motor requirements and acoustic correlates.
Highlights
Speech and language are realized as acoustic outputs of an aeromechanical system that is coordinated by a vast brain and muscular network
We examined the neural representations of segmental features in the context of fluent, continuous speech production
We found that the representation of place of articulation involved broad networks of brain regions during all phases of speech production: preparation, execution and monitoring
Summary
Speech and language are realized as acoustic outputs of an aeromechanical system that is coordinated by a vast brain and muscular network. The interaction between neural structures, facial and vocal tract musculature, and respiration provides humans with a dynamic speech production system capable of forming simple sounds (e.g., mono-syllabic words) and complex sounds (e.g., fluent conversation) These sounds are often represented by phonemes and syllables, which are fundamental linguistic bases for constructing both simple and complex speech production (e.g., the “b” in “bad” is an example of a phoneme while the “ba” is an example of a consonant-vowel (CV) syllable), which in turn correspond to stereotyped vocaltract movements resulting in acoustic speech output. These levels of processing have been well investigated and were summarized in a meta-analysis of neuroimaging, electrophysiology and neuro-stimulation studies of speech and language
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