Measuring Neuronal Avalanches to Inform Brain-computer Interfaces

Overview

Journal iScience

Publisher Cell Press

Date 2024 Jan 16

PMID 38226174

Authors

Marie-Constance Corsi

Pierpaolo Sorrentino

Denis Schwartz

Nathalie George

Leonardo L Gollo

Sylvain Chevallier

Laurent Hugueville

Ari E Kahn

Sophie Dupont

Danielle S Bassett

Viktor Jirsa

Fabrizio de Vico Fallani

Affiliations

Soon will be listed here.

Abstract

Large-scale interactions among multiple brain regions manifest as bursts of activations called neuronal avalanches, which reconfigure according to the task at hand and, hence, might constitute natural candidates to design brain-computer interfaces (BCIs). To test this hypothesis, we used source-reconstructed magneto/electroencephalography during resting state and a motor imagery task performed within a BCI protocol. To track the probability that an avalanche would spread across any two regions, we built an avalanche transition matrix (ATM) and demonstrated that the edges whose transition probabilities significantly differed between conditions hinged selectively on premotor regions in all subjects. Furthermore, we showed that the topology of the ATMs allows task-decoding above the current gold standard. Hence, our results suggest that neuronal avalanches might capture interpretable differences between tasks that can be used to inform brain-computer interfaces.

Citing Articles

Neuronal avalanches in temporal lobe epilepsy as a noninvasive diagnostic tool investigating large scale brain dynamics.

Corsi M, Troisi Lopez E, Sorrentino P, Cuozzo S, Danieli A, Bonanni P Sci Rep. 2024; 14(1):14039.

PMID: 38890363 PMC: 11189588. DOI: 10.1038/s41598-024-64870-3.

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