Frontiers in pharmacology
January 1, 2023
Klemens Egger, Frederik Gudmundsen, Naja Støckel Jessen et al.
17 citations
Co-administration of harmine with DMT in rats increased brain DMT levels by inhibiting its metabolism to indole-3-acetic acid, yet no significant occupancy of serotonin 5-HT2A receptors by DMT was detected, even at brain DMT concentrations up to 11.3 µM. Low doses of DMT and/or harmine did not significantly alter brain glucose metabolism as measured by [18F]FDG-PET. These preliminary findings suggest that the role of MAO-A inhibition in potentiating DMT's psychedelic effects may be more complex than previously assumed, and further dose-response studies are needed.
May 28, 2024
Frederik Gudmundsen, Julia Czurylo, Camilla Trang Vo et al.
1 citation
preprint
Three serotonergic psychedelics—psilocybin, LSD, and 2C-B—produce distinct acute and long-term changes in rat brain metabolic activity and connectivity. Psilocybin uniquely alters connectivity between cortical regions including the orbitofrontal, medial prefrontal, and insula cortex, as well as with the dorsal striatum, thalamus, and hippocampus. LSD and 2C-B share more similar effects, centered on acute inhibition of the anterior cingulate cortex, increased activity and connectivity between the amygdala and hypothalamus, and heightened activity in dopamine-rich regions of the ventral tegmental area and substantia nigra. These distinct neural patterns may guide which psychedelic drug could be most beneficial for specific neuropsychiatric disorders.
Neuropharmacology
February 9, 2026
Mikael Palner, Elisabeth Kolesnik, Christina Baun et al.
The study tested whether the psychedelic compound N,N-dimethyltryptamine (DMT) exists naturally in the mammalian brain and acts as a co-transmitter with serotonin. In rats, blocking monoamine oxidase with pargyline did not allow detection of endogenous DMT, while blocking acidic metabolite transport with probenecid slightly elevated the DMT metabolite 3-indoleacetic acid, likely from tryptamine. Exogenous DMT was rapidly taken up and cleared from the brain, with peak concentrations at 45 minutes and near-complete washout by 210 minutes. Blocking serotonin reuptake or vesicular monoamine transporters did not alter DMT levels. The results do not support the hypothesis that DMT is an endogenous co-transmitter with serotonin.
Open Access CRIS of the University of Bern
February 9, 2026
Mikael Palner, Elisabeth Kolesnik, Christina Baun et al.
The mammalian brain may contain an endogenous pool of the psychedelic N,N-dimethyltryptamine (DMT), possibly acting as a co-transmitter with serotonin. In rats, inhibiting monoamine oxidase with pargyline did not make endogenous DMT detectable, while probenecid slightly elevated the acidic metabolite 3-indoleacetic acid (3-IAA), suggesting formation from tryptamine, especially in the striatum. After administering DMT plus harmine, peak brain DMT occurred at 45 minutes and peak 3-IAA at 60 minutes, with nearly complete washout by 210 minutes. Escitalopram did not alter exogenous DMT or 3-IAA disposition, and dihydrotetrabenazine slightly increased 3-IAA in some regions. The results do not support an endogenous DMT pool or retention of exogenous DMT in serotonin terminals.