Skip to content

Karim Jerbi

Cognitive & Computational Neuroscience Lab, Psychology Department, University of Montreal, Montreal, QC, Canada.

6 papers in the library · 75 citations · publishing 2023-2026

Papers

Critical dynamics in spontaneous EEG predict anesthetic-induced loss of consciousness and perturbational complexity.

Communications biology August 5, 2024 Charlotte Maschke, Jordan O'Byrne, Michele Angelo Colombo et al. 50 citations

Consciousness may depend on brain activity poised at criticality—a state with complex patterns and high sensitivity to disruption. Analyzing resting-state EEG from healthy volunteers under propofol, xenon, or ketamine anesthesia, the study found that unconsciousness (from propofol or xenon) shifted brain dynamics away from avalanche criticality and the edge of chaos. Ketamine anesthesia preserved consciousness (vivid dreams) and criticality. Dynamical properties from resting EEG accurately predicted individual values of the perturbational complexity index (PCI), a TMS-based consciousness measure. The findings link perturbational complexity to criticality and suggest criticality is necessary for consciousness.

Mindfulness meditation styles differently modulate source-level MEG microstate dynamics and complexity

Frontiers in Neuroscience February 2, 2024 Antea D’Andrea, Pierpaolo Croce, Jordan O’Byrne et al. 13 citations

Theravada Buddhist monks with extensive meditation experience underwent magnetoencephalography during focused attention meditation, open monitoring meditation, and resting states. Brain microstate coverage and occurrence differed between meditation and rest and between the two meditation styles. The Hurst exponent, a measure of long-range memory in brain dynamics, was lower during both meditation conditions than during rest. Lempel-Ziv complexity, which quantifies signal complexity, increased progressively from rest to focused attention meditation to open monitoring meditation. These changes in brain criticality indices suggest that meditation shifts brain dynamics toward a more critical state, paralleling changes in cognitive state.

Criticality of resting-state EEG predicts perturbational complexity and level of consciousness during anesthesia.

bioRxiv : the preprint server for biology October 31, 2023 Charlotte Maschke, Jordan O'Byrne, Michele Angelo Colombo et al. 7 citations preprint

Consciousness may depend on brain activity poised at criticality, a state with optimal computational properties. Electroencephalograms were recorded from healthy, unresponsive volunteers under propofol, xenon, or ketamine anesthesia. Ketamine spared consciousness (vivid dreams), allowing separation of unresponsiveness from unconsciousness. Unconscious states showed a departure from both the edge of activity propagation and the edge of chaos. The perturbational complexity index (PCI), a sensitive consciousness measure, was predicted from these dynamical properties with a mean absolute error below 7%. Results link PCI to criticality and support criticality's role in consciousness.

Divergent Perception: Framing Creative Cognition Through the Lens of Sensory Flexibility

The Journal of Creative Behavior December 24, 2024 Antoine Bellemare‐Pepin, Karim Jerbi 4 citations

Creativity relies not only on divergent thinking but also on perceptual flexibility, especially when engaging with ambiguous stimuli. The authors propose a framework linking creativity to perception through sensory affordances, highlighting pareidolia—seeing familiar patterns in noise—as a key mechanism for generating novel ideas. They introduce "divergent perception" to describe active engagement with ambiguous sensory information, suggesting this process may explain heightened creativity in psychedelic and psychotic states. The role of attention in this process is explored, and future research directions are outlined, including manipulating stimulus characteristics and examining interactions between bottom-up and top-down cognitive processes.

LSD Reconfigures Cortical Dynamics Through Faster Brain Rhythms and Increased Fractal Dimension

bioRxiv (Cold Spring Harbor Laboratory) January 29, 2026 Venkatesh Subramani, Timothy Nest, Annalisa Pascarella et al. 1 citation

LSD alters brain activity by increasing alpha and beta brain-wave frequencies while genuinely reducing oscillatory power, with these effects showing distinct cortical patterns. The drug also flattens the aperiodic 1/f spectral slope and increases neural signal fractality and complexity, particularly in sensory, language, emotion, and imagery-related networks, while sparing motor cortex. Machine learning identified peak-frequency shifts, aperiodic parameters, and complexity measures as key discriminators of the psychedelic state. Music did not amplify these neural signatures and showed a trend toward attenuation. These findings provide a comprehensive account of how LSD reorganizes large-scale human brain dynamics.

LSD Relaxes Structural Constraints on Brain Dynamics and Default Mode Decoupling Tracks Ego Dissolution

bioRxiv (Cold Spring Harbor Laboratory) March 5, 2026 Venkatesh Subramani, Annalisa Pascarella, Jérémy Brunel et al.

Lysergic acid diethylamide (LSD) loosens the brain's usual alignment between anatomical structure and neural activity in a frequency-dependent way. Low-frequency brain waves (theta, alpha, beta) become less constrained by the structural connectome, indicating a global relaxation of large-scale dynamics. High-frequency gamma activity shows selective reorganization rather than uniform disruption. Greater gamma-band decoupling within core default-mode network regions predicts the intensity of ego dissolution across individuals. LSD does not cause indiscriminate disintegration but drives system-specific rebalancing: visual and attentional systems decouple while auditory networks strengthen coupling. These findings suggest psychedelic states emerge from frequency-dependent relaxation of structural constraints, with default-mode reorganization as a neural correlate of ego dissolution.