Nature communications
September 20, 2024
Václav Havel, Andrew C Kruegel, Benjamin Bechand et al.
18 citations
A new class of iboga alkaloids, called oxa-iboga, was created by modifying the iboga molecular structure to replace a key component with a benzofuran ring. These compounds lack the heart rhythm risks (proarrhythmic effects) of ibogaine and noribogaine when tested on human heart cells. In male rats, oxa-iboga compounds were more effective than ibogaine at reducing opioid use. They act as potent kappa opioid receptor agonists but produce different behavioral effects than typical kappa agonists. A single dose or short treatment with oxa-noribogaine led to long-lasting reductions in morphine, heroin, and fentanyl intake, reversed persistent opioid-induced pain sensitivity, and suppressed drug-seeking behavior in relapse models. These compounds offer a mechanistically distinct approach to treating opioid use disorder.
bioRxiv (Cold Spring Harbor Laboratory)
July 23, 2021
Václav Havel, Andrew C. Kruegel, Benjamin Bechand et al.
3 citations
preprint
A new class of iboga alkaloids, called oxa-iboga, was created by modifying the iboga skeleton to include a benzofuran group. These compounds act as potent kappa opioid receptor agonists but show atypical behavioral effects compared to standard kappa psychedelics. Oxa-noribogaine, a key oxa-iboga compound, demonstrated greater therapeutic efficacy in rat models of opioid use than noribogaine, with no cardiac pro-arrhythmic potential. A single dose produced long-lasting suppression of morphine and fentanyl intake, and a short treatment regimen persistently reduced morphine intake and reinforcing efficacy. It also suppressed drug seeking in relapse models and elevated neurotrophin proteins in brain regions linked to addiction, suggesting targeted neuroplasticity. Oxa-iboga compounds are candidates for a novel pharmacotherapy for opioid use disorder.
Nature Structural & Molecular Biology
June 22, 2026
Qianru Jiang, Jianming Han, Eve Fine et al.
Ketamine, used for treatment-resistant depression and severe pain, acts primarily by blocking the N-methyl-D-aspartate receptor, but its therapeutic and abuse-related effects may involve additional targets. Structural evidence shows that ketamine and its analog phencyclidine (PCP) can directly bind to and activate human opioid receptors. The study identifies key molecular motifs involved in this binding and efficacy modulation, and also reveals the structure of the ligand-free state of the κ opioid receptor. Ketamine exhibits more dynamic binding than PCP at the orthosteric site, which may explain its distinct pharmacology. These findings indicate that opioid receptors are important for understanding ketamine's clinical versatility.