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EEG brain reconfiguration during meditation-induced extended cessation of consciousness: A dense-sampling multi-participant microstate study

David Zarka, Winson F.z. Yang, Abel Rassat, Ruby Potash, Terje Sparby, Matthew D. Sacchet

bioRxiv Preprint Server February 10, 2026 preprint DOI: 10.64898/2026.02.10.705005 via bioRxiv

Summary

Extended cessation is a rare meditative state where conscious experience temporarily stops, followed by heightened perception and emotional balance. In five highly trained meditators, brain electrical activity measured with EEG showed changes in two microstates linked to self-referential processing. Microstate B became less frequent and shorter, while microstate C became more frequent and longer. Transition patterns also shifted, with more transitions from microstates A and B to C, and fewer from A to B. These findings suggest a reconfiguration of self-referential brain networks during extended cessation.

Study at a glance

Design observational study
Sample size 5
Population highly trained meditators
Key finding Extended cessation involves less frequent and shorter microstate B and more frequent and longer microstate C, along with altered transition probabilities, indicating reconfiguration of self-referential processing.

Abstract

Extended cessation (EC) is a rare, non-ordinary meditative endpoint characterized by a temporary absence of reportable phenomenal experience, followed by an extraordinary perceptual vividness, openness, equanimity and affective balance. EC thus offers a unique, non-pharmacological window into the brain dynamics underlying suspension of conscious experience and the subsequent psychological transformations. The present study investigated whole-brain electrophysiological changes induced by EC using a dense-sampling electroencephalographic microstate analysis, in five highly trained meditators. Temporal parameters and transition probabilities of canonical microstates during EC were compared with two control conditions (counting and memory tasks) across six frequency bands (broadband, delta, theta, alpha, beta, gamma). EC was characterized by alterations in global explained variance and coverage of microstates B and C, both associated with self-referential processing. Specifically, EC involved less frequent and shorter occurrences of microstate B, and more frequent and longer occurrences of microstate C. Transition probabilities also reconfigured: transitions from A and B to C increased, whereas transitions from A to B decreased. These broadband effects were distributed across delta, theta, and beta frequency sub-bands. Additional band-specific changes emerged for microstate A and D. Delta band showed longer microstate A and increased B-to-A transitions during EC, while beta band showed less frequent and shorter D and decreased bidirectional B-to-D transitions. These scalp-level findings support a precision re-weighting account of EC, reflecting self-referential reconfigurations with enhanced sensory-anchored inflow. This study provides initial evidence for the neurophysiological correlates of EC, with potential implications for human wellbeing.

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