Nature
October 18, 2023
Shuangshuang Ma, Min Chen, Yihao Jiang et al.
202 citations
Ketamine's antidepressant effects last much longer than its short half-life because the drug becomes trapped in NMDA receptors in the lateral habenula, and its release depends on neural activity. In mice, a single injection suppressed burst firing and blocked NMDA receptors in the lateral habenula for up to 24 hours. This sustained action results from use-dependent trapping, not endocytosis. By activating the lateral habenula and opening local NMDA receptors at different plasma ketamine concentrations, the duration of antidepressant effects could be shortened or prolonged. These findings explain the mechanism behind ketamine's sustained effects and suggest ways to modulate its therapeutic duration.
Advanced science (Weinheim, Baden-Wurttemberg, Germany)
April 2, 2025
Cong Lin, Xiaoxuan Zhou, Mingqi Li et al.
14 citations
In a mouse model of inflammation-induced depression, S-ketamine (S-KET) reduced depressive-like behaviors and lowered pro-inflammatory factors in the medial prefrontal cortex, while R-ketamine (R-KET) did not. S-KET bound directly to the protein SIRT2 at the Q167 residue, enhancing its interaction with NF-κB subunit p65, which reduced acetylation and suppressed pro-inflammatory gene expression. Experiments using RNA interference, a SIRT2 inhibitor (AK-7), and pharmacological blockade confirmed that SIRT2 is essential for these effects. The findings indicate that SIRT2 mediates the therapeutic actions of S-KET, suggesting a target for treating inflammation-associated depression.
ACS Pharmacology & Translational Science
May 15, 2025
Haojiang Zhai, Hongshuang Wang, Haohong Li et al.
3 citations
Psychedelics like psilocybin, LSD, and DMT may alter sleep architecture, particularly by influencing rapid eye movement (REM) sleep and vivid dreaming. This viewpoint suggests these substances could have therapeutic potential for sleep disorders, though their impact on sleep remains underexplored. The authors provide a perspective on how psychedelics might affect sleep phases and dreaming, opening an emerging area for sleep therapy.
ACS Pharmacology & Translational Science
July 8, 2025
Miyuan Zhang, Haiyan Zhai, Liu Yang et al.
1 citation
Psilocin, the active metabolite of psilocybin, induces psychedelic-like behavior in male mice by activating neurons in the medial prefrontal cortex (mPFC). Using c-Fos immunofluorescent labeling, the mPFC was the only brain region among several tested that was specifically associated with the head twitch response (HTR), a behavioral marker of psychedelic activity. A picomolar dose of psilocin directly into the mPFC triggered significant HTR. Optogenetic activation of these neurons increased spontaneous HTR, while acute inhibition suppressed drug-induced HTR. The findings establish the mPFC as a critical regulator of psilocin's psychedelic effects, offering insights for improving the clinical safety and therapeutic use of psychedelics.