A data-driven network decomposition of the temporal, spatial, and spectral dynamics underpinning visual-verbal working memory processes

Journal article

Background: Systems neuroscience studies have shown that baseline brain activity can be categorized into largescale networks (resting-state-networks, RNSs), with influence on cognitive abilities and clinical symptoms. These insights have guided millimeter-precise selection of brain stimulation targets based on RSNs. Concurrently, Transcranial Magnetic Stimulation (TMS) studies revealed that baseline brain states, measured by EEG signal power or phase, affect stimulation outcomes. However, EEG dynamics in these studies are mostly limited to single regions or channels, lacking the spatial resolution needed for accurate network-level characterization. Objective: We aim at mapping brain networks with high spatial and temporal precision and to assess whether the occurrence of specific network-level-states impact TMS outcome. To this end, we will identify large-scale brain networks and explore how their dynamics relates to corticospinal excitability. Methods: This study leverages Hidden Markov Models to identify large-scale brain states from pre-stimulus source space high-density-EEG data collected during TMS targeting the left primary motor cortex in twenty healthy subjects. The association between states and fMRI-defined RSNs was explored using the Yeo atlas, and the trialby-trial relation between states and corticospinal excitability was examined. Results: We extracted fast-dynamic large-scale brain states with unique spatiotemporal and spectral features resembling major RSNs. The engagement of different networks significantly influences corticospinal excitability, with larger motor evoked potentials when baseline activity was dominated by the sensorimotor network. Conclusions: These findings represent a step forward towards characterizing brain network in EEG-TMS with both high spatial and temporal resolution and underscore the importance of incorporating large-scale network dynamics into TMS experiments

Authors: Rossi, C; Vidaurre, D; Costers, L; Akbarian, F; Woolrich, M

• Publication status: Published
• Peer review status: Peer reviewed
• Publisher: Nature Research
• Journal: Communications Biology
• Volume: 6
• Issue: 1
• Pages: 1079-1079
• Publication date: 2023-10-23
• DOI: 10.1038/s42003-023-05448-z
• EISSN: 2399-3642
• ISSN: 2399-3642
• Language: English
• Keywords: Computer science; Psychology; Baddeley's model of working memory; Neuroscience; Magnetoencephalography; Electroencephalography; Neurophysiology; Cognitive psychology; Short-term memory; Artificial intelligence; Network dynamics; Cognition; Working memory