Jon Brennan and Coauthors Publish Paper on Neural Responses to Phonotactics in Autism Spectrum Disorder
“Magnetoencephalography shows atypical sensitivity to linguistic sound sequences in autism spectrum disorder” was coauthored by Jon Brennan (University of Michigan), Neelima Wagley (University of Michigan), Ioulia Kovelman (University of Michigan), Susan M. Bowyer (Henry Ford Hospital), Annette E. Richard (University of Michigan), and Renee Lajiness-O’Neill (Eastern Michigan University).
The results of their research indicates that early auditory processing abnormalities present in school-aged children with ASD have cascading effects on phonological processing when compared to those without ASD. Read the findings in their entirety here!
Jon is an assistant professor of linguistics at U-M. He directs the Computational Linguistics Lab and studies the mental structures and computations used to understand words and sentences, with a focus on how these processes are implemented in the brain.
Abstract
Neuroscientific evidence points toward atypical auditory processing in individuals with autism spectrum disorders (ASD), and yet, the consequences of this for receptive language remain unclear. Using magnetoencephalography and a passive listening task, we test for cascading effects on speech sound processing. Children with ASD and age-matched control participants (8–12 years old) listened to nonce linguistic stimuli that either did or did not conform to the phonological rules that govern consonant sequences in English (e.g. legal ‘vimp’ vs. illegal ‘vimk’). Beamformer source analysis was used to isolate evoked responses (0.1–30 Hz) to these stimuli in the left and the right auditory cortex. Right auditory responses from participants with ASD, but not control participants, showed an attenuated response to illegal sequences relative to legal sequences that emerged around 330 ms after the onset of the critical phoneme. These results suggest that phonological processing is impacted in ASD, perhaps because of cascading effects from disrupted initial acoustic processing.
Learn more about Jon and his research!