The Journal of pharmacology and experimental therapeutics
February 1, 2014
Patrick Thurner, Anna Stary-Weinzinger, Hend Gafar et al.
41 citations
Ibogaine, a psychoactive alkaloid used to treat addiction, can cause dangerous heart rhythm problems by blocking hERG potassium channels. Experiments on mammalian kidney cells expressing hERG channels showed that block occurred from either side of the cell membrane and depended on pH. Block happened only when channels were activated, not when resting. Stronger depolarizations increased block speed and extent. The drug shifted channel activation and inactivation to more negative voltages, slowed deactivation, and accelerated inactivation. Mutations Y652A and F656A reduced ibogaine's potency, but an inactivation-deficient mutant remained sensitive. Molecular docking suggested binding inside the channel cavity regardless of ibogaine's protonation state. Kinetic modeling indicated preferential binding to open and inactivated states.
Journal of neurochemistry
September 1, 2024
Ana Sofia Alberto-Silva, Selina Hemmer, Hailey A Bock et al.
10 citations
Three new chemical variants of MDMA—ODMA, TDMA, and SeDMA—show similar activity at serotonin, dopamine, and norepinephrine transporters but reduced activity at 5-HT2A/2B/2C receptors compared to MDMA. They also differ in liver metabolism, with N-demethylation as the only shared route and no phase II metabolites formed. TDMA showed faster clearance. The analogs interacted more weakly with organic cation transporters and plasma membrane monoamine transporter. These bioisosteres may offer therapeutic alternatives to MDMA with a reduced off-target profile, but further studies are needed to determine if they pose lower risks.
bioRxiv : the preprint server for biology
April 11, 2024
Ana Sofia Alberto-Silva, Selina Hemmer, Hailey A Bock et al.
preprint
Three new chemical variants of MDMA—ODMA, TDMA, and SeDMA—show similar activity at serotonin and dopamine transporters but reduced activity at serotonin 5-HT2A/2B/2C receptors, which may lower the risk of off-target side effects. They also differ from MDMA in how they are broken down by the liver, with fewer metabolic pathways and no phase II metabolites. The analogs interact more weakly with certain organic cation transporters. These findings suggest the new compounds could be promising therapeutic alternatives to MDMA for conditions like PTSD, though further research is needed to confirm whether they pose lower risks.