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Peter J. Hellyer

Imperial College London

2 papers in the library · 1,978 citations · publishing 2014

Papers

The entropic brain: a theory of conscious states informed by neuroimaging research with psychedelic drugs

Frontiers in Human Neuroscience January 1, 2014 Robin Carhart‐Harris, Robert Leech, Peter J. Hellyer et al. 1,289 citations

Entropy, a measure of uncertainty or disorder, is applied to brain function and consciousness, focusing on the psychedelic state induced by psilocybin. The psychedelic state is considered a primary or primitive state of consciousness, characterized by elevated entropy in brain function, including a greater repertoire of functional connectivity motifs that form and fragment over time. This suggests primary states may exhibit criticality, a transition zone between order and disorder. Normal waking consciousness suppresses entropy, operating just below criticality, which constrains cognition and enables metacognitive functions like reality-testing and self-awareness. Entry into primary states involves collapse of default-mode network activity and decoupling from medial temporal lobes. These hypotheses can be tested by comparing brain activity in REM sleep, early psychosis, normal waking consciousness, and anesthesia.

Homological scaffolds of brain functional networks

Journal of The Royal Society Interface October 29, 2014 Giovanni Petri, Paul Expert, Federico Turkheimer et al. 689 citations

Functional brain networks can be studied through homological cycles—topological objects that capture mesoscopic structure in weighted correlation networks. A new method, homological scaffolds, compactly represents these cycles and makes them amenable to standard network analysis. Applied to resting-state fMRI data from 15 healthy volunteers given placebo or psilocybin, the homological structure of brain activity changed dramatically after psilocybin, producing many transient, low-stability cycles and a few persistent ones absent under placebo.