1. Low-dimensional controllability of brain networks.
- Author
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Ben Messaoud R, Le Du V, Bousfiha C, Corsi MC, Gonzalez-Astudillo J, Kaufmann BC, Venot T, Couvy-Duchesne B, Migliaccio L, Rosso C, Bartolomeo P, Chavez M, and De Vico Fallani F
- Subjects
- Humans, Models, Neurological, Computer Simulation, Algorithms, Brain physiology, Connectome methods, Nerve Net physiology, Computational Biology
- Abstract
Identifying the driver nodes of a network has crucial implications in biological systems from unveiling causal interactions to informing effective intervention strategies. Despite recent advances in network control theory, results remain inaccurate as the number of drivers becomes too small compared to the network size, thus limiting the concrete usability in many real-life applications. To overcome this issue, we introduced a framework that integrates principles from spectral graph theory and output controllability to project the network state into a smaller topological space formed by the Laplacian network structure. Through extensive simulations on synthetic and real networks, we showed that a relatively low number of projected components can significantly improve the control accuracy. By introducing a new low-dimensional controllability metric we experimentally validated our method on N = 6134 human connectomes obtained from the UK-biobank cohort. Results revealed previously unappreciated influential brain regions, enabled to draw directed maps between differently specialized cerebral systems, and yielded new insights into hemispheric lateralization. Taken together, our results offered a theoretically grounded solution to deal with network controllability and provided insights into the causal interactions of the human brain., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2025 Ben Messaoud et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)
- Published
- 2025
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