Science Advances
June 14, 2023
Leor Roseman, Christopher Timmermann, Daniel Golkowski et al.
65 citations
The effects of mind-altering drugs on brain function arise from complex interactions with multiple neurotransmitter systems, not just one. By linking the distribution of 19 neurotransmitter receptors and transporters (measured with PET) to changes in functional connectivity (measured with fMRI) caused by 10 drugs—anesthetics (propofol, sevoflurane, ketamine), psychedelics (LSD, psilocybin, DMT, ayahuasca), and others (MDMA, modafinil, methylphenidate)—the work shows a many-to-many mapping between drug effects and neurotransmitter systems. The drugs' impacts follow hierarchical gradients of brain structure and function, and regional susceptibility to drug-induced changes mirrors susceptibility to structural alterations from brain disorders.
bioRxiv (Cold Spring Harbor Laboratory)
September 18, 2023
Sepehr Mortaheb, Larry D. Fort, Natasha L. Mason et al.
7 citations
preprint
Psilocybin increases functional connectivity across the brain and induces a recurrent hyperconnected pattern with low BOLD signal amplitude, suggesting heightened cortical arousal. These brain dynamics are linked to feelings of oceanic boundlessness and visionary restructuralization, as measured by the 5-Dimensional Altered States of Consciousness Rating Scale. The brain's tendency to enter this hyperconnected-hyperarousal pattern under psilocybin may enable variant mental associations. For the first time, these findings connect brain dynamics with phenomenological alterations, offering new insights into the neurophenomenology and neurophysiology of the psychedelic state.
bioRxiv (Cold Spring Harbor Laboratory)
July 13, 2022
Andrea I. Luppi, Justine Y. Hansen, R. Adapa et al.
5 citations
preprint
Psychoactive drugs reshape brain function by engaging multiple neurotransmitter systems simultaneously. By mapping the distribution of 19 neurotransmitter receptors and transporters (via PET) and the connectivity changes caused by 10 drugs (anesthetics, psychedelics, and stimulants), the study shows that drug effects are organized along hierarchical gradients of brain structure and function. Additionally, brain regions susceptible to drug-induced changes are also vulnerable to structural alterations from brain disorders. These findings reveal systematic links between molecular neurochemistry and large-scale functional reorganization.
October 17, 2024
Thomas Andrillon, Antoine Lutz, Jennifer Windt et al.
4 citations
preprint
Mind blanking (MB) refers to moments during wakefulness when people report no specific thoughts. This review maps MB by examining its reportable expressions, brain signatures, and links to meditative practices and sleep (white dreams). The authors propose a mechanistic account linking MB to changes at physiological, neural, and cognitive levels. They argue that ongoing experience varies in richness and that seemingly contentless events are distinct mental states with their own diversity, challenging the view of the mind as primarily content-oriented.
bioRxiv (Cold Spring Harbor Laboratory)
June 25, 2024
Milan van Maldegem, Jakub Vohryzek, Selen Atasoy et al.
2 citations
preprint
Ketamine, a dissociative anesthetic, produces different brain dynamics at anesthetic versus sub-anesthetic doses. Using connectome harmonic decomposition (CHD) to analyze resting-state fMRI data from volunteers during ketamine-induced unresponsiveness, the study found increased prevalence of localized harmonics, similar to patterns seen in psychedelic states induced by LSD or psilocybin. This contrasts with traditional GABAergic sedation (e.g., propofol), where global harmonics increase with higher doses. The results indicate that ketamine-induced unresponsiveness does not necessarily suppress conscious experience and influences connectome harmonics oppositely to GABAergic hypnotics. CHD may track alterations in conscious awareness rather than behavioral responsiveness.