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Maximizing brain networks engagement via individualized connectome-wide target search
Title / Series / Name
Publication Volume
Publication Issue
Pages
Editors
Keywords
Network control theory
Noninvasive brain stimulation
Personalized care
Transcranial magnetic stimulation
General Neuroscience
Biophysics
Neurology (clinical)
Noninvasive brain stimulation
Personalized care
Transcranial magnetic stimulation
General Neuroscience
Biophysics
Neurology (clinical)
URI
https://hdl.handle.net/20.500.14018/27136
Abstract
Background: In recent years, the possibility to noninvasively interact with the human brain has led to unprecedented diagnostic and therapeutic opportunities. However, the vast majority of approved interventions and approaches still rely on anatomical landmarks and rarely on the individual structure of networks in the brain, drastically reducing the potential efficacy of neuromodulation. Objective: Here we implemented a target search algorithm leveraging on mathematical tools from Network Control Theory (NCT) and whole brain connectomics analysis. By means of computational simulations, we aimed to identify the optimal stimulation target(s)— at the individual brain level— capable of reaching maximal engagement of the stimulated networks’ nodes. Results: At the model level, in silico predictions suggest that stimulation of NCT-derived cerebral sites might induce significantly higher network engagement, compared to traditionally employed neuromodulation sites, demonstrating NCT to be a useful tool in guiding brain stimulation. Indeed, NCT allows us to computationally model different stimulation scenarios tailored on the individual structural connectivity profiles and initial brain states. Conclusions: The use of NCT to computationally predict TMS pulse propagation suggests that individualized targeting is crucial for more successful network engagement. Future studies will be needed to verify such prediction in real stimulation scenarios.
Topic
Publisher
Place of Publication
Type
Journal article
Date
2022-11-01
Language
ISBN
Identifiers
10.1016/j.brs.2022.09.011