Criticality of resting-state EEG predicts perturbational complexity and level of consciousness during anesthesia.
Charlotte MaschkeJordan O'ByrneMichele Angelo ColomboMelanie BolyOlivia GosseriesSteven LaureysMario RosanovaKarim JerbiStefanie Blain-MoraesPublished in: bioRxiv : the preprint server for biology (2023)
Consciousness has been proposed to be supported by electrophysiological patterns poised at criticality, a dynamical regime which exhibits adaptive computational properties, maximally complex patterns and divergent sensitivity to perturbation. Here, we investigated dynamical properties of the resting-state electroencephalogram of healthy subjects undergoing general anesthesia with propofol, xenon or ketamine. We then studied the relation of these dynamic properties with the perturbational complexity index (PCI), which has shown remarkably high sensitivity in detecting consciousness independent of behavior. All participants were unresponsive under anesthesia, while consciousness was retained only during ketamine anesthesia (in the form of vivid dreams)., enabling an experimental dissociation between unresponsiveness and unconsciousness. We estimated (i) avalanche criticality, (ii) chaoticity, and (iii) criticality-related measures, and found that states of unconsciousness were characterized by a distancing from both the edge of activity propagation and the edge of chaos. We were then able to predict individual subjects' PCI (i.e., PCI max ) with a mean absolute error below 7%. Our results establish a firm link between the PCI and criticality and provide further evidence for the role of criticality in the emergence of consciousness.
Keyphrases
- resting state
- functional connectivity
- percutaneous coronary intervention
- coronary artery disease
- acute myocardial infarction
- acute coronary syndrome
- antiplatelet therapy
- st segment elevation myocardial infarction
- st elevation myocardial infarction
- atrial fibrillation
- coronary artery bypass grafting
- pain management
- density functional theory
- high resolution
- atomic force microscopy