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Justine Y. Hansen

Montreal Neurological Institute and Hospital

3 papers in the library · 70 citations · publishing 2022-2026

Papers

In vivo mapping of pharmacologically induced functional reorganization onto the human brain’s neurotransmitter landscape

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.

Mapping Pharmacologically-induced Functional Reorganisation onto the Brain’s Neurotransmitter Landscape

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.

The blueprint of human functional architecture shifts from cognition to anatomy during perturbations of consciousness

bioRxiv Preprint Server June 7, 2026 Andrea I. Luppi, Dragana Manasova, Justine Y. Hansen et al. preprint

Functional connectivity in the awake human brain is shaped primarily by cognitive co-activation—the tendency of brain regions to work together during mental tasks—more than by structural or molecular constraints. This predominance is systematically lost across five datasets involving pharmacological and pathological perturbations of consciousness (chronic disorders of consciousness; anesthesia with sevoflurane, propofol, or ketamine), when cognition is disconnected from the environment or abolished. During such states, the predictors of functional architecture shift away from cognitive co-activation and toward anatomical and molecular constraints.