Frontiers in Psychiatry
June 30, 2023
Colleen E. Charlton, Povilas Karvelis, Roger S. McIntyre et al.
7 citations
Suicide claims over 700,000 lives each year. Ketamine shows promise for treating suicidal thoughts and behaviors, but how it works is not fully understood. Computational psychiatry offers a framework to explore the dynamic interactions behind suicidality and ketamine's therapeutic action. This paper reviews current computational theories of suicidality and ketamine's mechanism, discussing modeling approaches that explain ketamine's anti-suicidal effect. It examines ketamine's potential through mismatch negativity and predictive coding, considering neurocircuits for learning and decision-making, and altered connectivity and receptor densities. Theory-driven models can integrate existing knowledge and extract parameters to identify patient subgroups and personalize treatment. Future studies should optimize task design and evaluate set, setting, and psychedelic-assisted therapy.
bioRxiv (Cold Spring Harbor Laboratory)
November 7, 2025
Gabrielle Allohverdi, Milad Soltanzadeh, André Schmidt et al.
preprint
Ketamine and psilocybin, two hallucinogenic compounds being explored as treatments for major depressive disorder, affect sensory learning in the brain differently. By combining computational modeling with electroencephalography (EEG) data from a prior experiment, researchers analyzed how these drugs alter the brain's processing of unexpected sounds during an auditory task. Ketamine produced a larger reduction in the influence of sensory precision between 207 and 316 milliseconds after a sound, peaking at 277 milliseconds in frontal central brain regions, while psilocybin showed no significant effect in that measure. Both drugs reduced the expression of belief precision between 160 and 184 milliseconds, peaking at 172 milliseconds.
Research Square
September 26, 2024
Shona G. Allohverdi, Milad Soltanzadeh, André Schmidt et al.
Ketamine and psilocybin affect sensory learning in the brain through different neural mechanisms. By combining computational modeling with EEG data from a previous study, researchers analyzed how these drugs alter the brain's processing of prediction errors during an auditory task. Ketamine produced a larger reduction in sensory precision from 207 to 316 milliseconds after sounds, peaking at 277 milliseconds in frontal central brain regions, while psilocybin showed no significant effect on this measure. Both drugs reduced belief precision between 160 to 184 milliseconds, peaking at 172 milliseconds. For higher-level volatility prediction errors, ketamine reduced expression while psilocybin had no effect at 312 milliseconds. These distinct effects could inform tailored therapies for major depressive disorder.