Psilocin acutely disrupts sleep and affects local but not global sleep homeostasis in laboratory mice
Christopher W. Thomas, Cristina Blanco-duque, Benjamin Bréant, Guy M. Goodwin, Trevor Sharp, David M. Bannerman, Vladyslav V. Vyazovskiy
bioRxiv Preprint Server February 16, 2021 preprint DOI: 10.1101/2021.02.16.431276 via bioRxiv
Summary
Psilocin administration in mice resulted in delayed REM sleep onset and reduced NREM sleep maintenance for about 3 hours, with an enhanced 4 Hz oscillation observed in EEG readings. However, there were no long-term changes in sleep-wake quantity, and psilocin did not affect the dynamics of sleep recovery after deprivation, although it decreased the recovery rate of sleep slow wave activity in certain brain regions. These findings suggest that psilocin influences sleep patterns, which may relate to its antidepressant effects.
Study at a glance
| Design | experimental study |
|---|---|
| Population | mice |
| Key finding | Psilocin affects both global vigilance state control and local sleep homeostasis. |
Abstract
Serotonergic psychedelic drugs, such as psilocin (4-hydroxy-N,N-dimethyltryptamine), profoundly alter the quality of consciousness through mechanisms which are incompletely understood. Growing evidence suggests that a single psychedelic experience can positively impact long-term psychological well-being, with relevance for the treatment of psychiatric disorders, including depression. A prominent factor associated with psychiatric disorders is disturbed sleep, and the sleep-wake cycle is implicated in the regulation of neuronal firing and activity homeostasis. It remains unknown to what extent psychedelic agents directly affect sleep, in terms of both acute arousal and homeostatic sleep regulation. Here, chronic in vivo electrophysiological recordings were obtained in mice to track sleep-wake architecture and cortical activity after psilocin injection. Administration of psilocin led to delayed REM sleep onset and reduced NREM sleep maintenance for up to approximately 3 hours after dosing, and the acute EEG response was associated primarily with an enhanced oscillation around 4 Hz. No long-term changes in sleep-wake quantity were found. When combined with sleep deprivation, psilocin did not alter the dynamics of homeostatic sleep rebound during the subsequent recovery period, as reflected in both sleep amount and EEG slow wave activity. However, psilocin decreased the recovery rate of sleep slow wave activity following sleep deprivation in the local field potentials of electrodes targeting medial prefrontal and surrounding cortex. It is concluded that psilocin affects both global vigilance state control and local sleep homeostasis, an effect which may be relevant for its antidepressant efficacy.