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Subcortical-cortical dynamical states of the human brain and their breakdown in stroke

Chiara Favaretto, Michele Allegra, Gustavo Deco, Nicholas V. Metcalf, Joseph C. Griffis, Gordon L. Shulman, Andrea Brovelli, Maurizio Corbetta

2022Nature Communications70 citationsDOIOpen Access PDF

Abstract

The mechanisms controlling dynamical patterns in spontaneous brain activity are poorly understood. Here, we provide evidence that cortical dynamics in the ultra-slow frequency range (<0.01-0.1 Hz) requires intact cortical-subcortical communication. Using functional magnetic resonance imaging (fMRI) at rest, we identify Dynamic Functional States (DFSs), transient but recurrent clusters of cortical and subcortical regions synchronizing at ultra-slow frequencies. We observe that shifts in cortical clusters are temporally coincident with shifts in subcortical clusters, with cortical regions flexibly synchronizing with either limbic regions (hippocampus/amygdala), or subcortical nuclei (thalamus/basal ganglia). Focal lesions induced by stroke, especially those damaging white matter connections between basal ganglia/thalamus and cortex, provoke anomalies in the fraction times, dwell times, and transitions between DFSs, causing a bias toward abnormal network integration. Dynamical anomalies observed 2 weeks after stroke recover in time and contribute to explaining neurological impairment and long-term outcome.

Topics & Concepts

ThalamusNeuroscienceBasal gangliaWhite matterCerebral cortexFunctional magnetic resonance imagingCortex (anatomy)HippocampusAmygdalaBiologyPsychologyMagnetic resonance imagingMedicineCentral nervous systemRadiologyFunctional Brain Connectivity StudiesAdvanced MRI Techniques and ApplicationsNeural dynamics and brain function
Subcortical-cortical dynamical states of the human brain and their breakdown in stroke | Litcius