Feindel Brain and Mind Seminar Series: Cortical–Subcortical Interactions Underlie Processing of Auditory Predictions Measured With 7T fMRI
La série Feindel Brain and Mind Seminar s’inscrit dans la ligne de pensée du Dr William Feindel (1918-2014), directeur du Neuro de 1972 à 1984, qui consiste à maintenir un lien constant entre pratique clinique et recherche. Les présentations porteront sur les dernières avancées et découvertes en neuropsychologie, en neurosciences cognitives et en neuro-imagerie.
Les scientifiques du Neuro, ainsi que des collègues et collaborateurs venus du milieu ou du monde entier, se chargeront des conférences. Cette série se veut un forum virtuel pour les chercheurs et les stagiaires en vue de favoriser les échanges interdisciplinaires sur les mécanismes des troubles cérébraux et cognitifs, leur diagnostic et leur traitement.
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Alberto Ara
Postdoctoral Fellow, The Neuro, McGill University
Abstract: Perception integrates both sensory inputs and internal models of the environment. In the auditory domain, predictions play a critical role because of the temporal nature of sounds. However, the precise contribution of cortical and subcortical structures in these processes and their interaction remain unclear. It is also unclear whether these brain interactions are specific to abstract rules or if they also underlie the predictive coding of local features. We used high-field 7T functional magnetic resonance imaging to investigate interactions between cortical and subcortical areas during auditory predictive processing. Volunteers listened to tone sequences in an oddball paradigm where the predictability of the deviant was manipulated. Perturbations in periodicity were also introduced to test the specificity of the response. Results indicate that both cortical and subcortical auditory structures encode high-order predictive dynamics, with the effect of predictability being strongest in the auditory cortex. These predictive dynamics were best explained by modeling a top–down information flow, in contrast to unpredicted responses. No error signals were observed to deviations of periodicity, suggesting that these responses are specific to abstract rule violations. Our results support the idea that the high-order predictive dynamics observed in subcortical areas propagate from the auditory cortex.
