5-MeO-DMT, a short-acting psychedelic, produces a dose-dependent increase in head-twitch response in mice that is shorter in duration than psilocybin at all doses tested. It also substantially suppresses social ultrasonic vocalizations during mating behavior. The compound causes long-lasting increases in dendritic spine density in the mouse medial frontal cortex, driven by an elevated rate of spine formation, but unlike psilocybin, it does not affect the size of dendritic spines. These findings reveal behavioral and neural mechanisms of 5-MeO-DMT, highlighting similarities and differences with psilocybin.
A pipeline using light sheet fluorescence microscopy to measure immediate early gene expression in mouse brain tissues, combined with machine learning, can classify psychoactive drugs including psilocybin, ketamine, and MDMA. In one-versus-rest tests, the exact drug was identified with 67% accuracy, far above the 12.5% chance level. Psilocybin was discriminated from 5-MeO-DMT, ketamine, MDMA, or acute fluoxetine with over 95% accuracy in pairwise comparisons. Shapley additive explanation identified brain regions driving the predictions. The approach offers a novel way to characterize and validate psychedelic and related compounds.