Critical‐like brain dynamics in a continuum from second-to first‐order phase transition

Wang, Sheng H.; Siebenhühner, Felix; Arnulfo, Gabriele; Myrov, Vladislav; Nobili, Lino; Breakspear, Michael; Palva, Satu; Palva, J. Matias

Title: Critical‐like brain dynamics in a continuum from second-to first‐order phase transition
Creator: Wang, Sheng H.; Siebenhühner, Felix; Arnulfo, Gabriele; Myrov, Vladislav; Nobili, Lino; Breakspear, Michael; Palva, Satu; Palva, J. Matias
Relation: Journal of Neuroscience Vol. 43, Issue 45, p. 7642-7656
Publisher Link: http://dx.doi.org/10.1523/JNEUROSCI.1889-22.2023
Publisher: Society for Neuroscience
Resource Type: journal article
Date: 2023
Description: The classic brain criticality hypothesis postulates that the brain benefits from operating near a continuous second‐order phase transition. Slow feedback regulation of neuronal activity could, however, lead to a discontinuous first‐order transition and thereby bistable activity. Observations of bistability in awake brain activity have nonetheless remained scarce and its functional significance unclear. Moreover, there is no empirical evidence to support the hypothesis that the human brain could flexibly operate near either a first‐ or second‐order phase transition despite such a continuum being common in models. Here, using computational modelling, we found bistable synchronization dynamics to emerge through elevated positive feedback and occur exclusively in a regime of critical‐like dynamics. We then assessed bistability in vivo with resting‐state magnetoencephalography in healthy adults (7 females, 11 males) and stereo‐electroencephalography in epilepsy patients (28 females, 36 males). This analysis revealed that a large fraction of the neocortices exhibited varying degrees of bistability in neuronal oscillations from 3 to 200 Hz. In line with our modelling results, the neuronal bistability was positively correlated with classic assessment of brain criticality across narrow‐band frequencies. Excessive bistability was predictive of epileptic pathophysiology in the patients whereas moderate bistability was positively correlated with task performance in the healthy subjects. These empirical findings thus reveal the human brain as a one‐of‐a‐kind complex system that exhibits critical‐like dynamics in a continuum between continuous and discontinuous phase transitions.
Subject: bistability; criticality; dynamics; epilepsy; resting-state; scale-free
Identifier: http://hdl.handle.net/1959.13/1495955
Identifier: uon:54087
Identifier: ISSN:0270-6474
Language: eng
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