[Metabolites of ecstasy and cytotoxicity effects]. / Métabolites de l'ecstasy et phénomènes de cytotoxicité

Intracerebroventricular injection of methylenedioxymethamphetamine (MDMA, ecstasy) in rats fails to reproduce long-term toxic effects observed after peripheral administration. Therefore, systemic metabolites would play an essential role in the development of cytotoxicity. In humans, the major metabolite is the 3,4-dihydroxymethamphetamine derivative (HHMA), which is easily oxidizable to the orthoquinone species. This can either participate to redox cycling generating semiquinone radicals and reactive oxygen species (ROS), or react with endogenous thiol derivatives yielding catechol-thioether conjugates whose the toxicity is not well established. A one pot electrochemical procedure has been developed allowing the synthesis of several catechol-thioether metabolites. Two in vitro assays have been used for evaluating their specific cytotoxicity. The first one is a bacterial assay, which shows that HHMA and some catechol-thioether conjugates can induce toxic phenomena leading to the formation of ROS, through redox cycling processes involving o-quinonoid species. The second one is an assay of cellular viability, performed on rat hippocampal pyramidal neurons. It confirms that some of these metabolites exhibit a noticeable cytotoxicity by markedly eliciting both necrosis and apoptosis markers.

[Biomimetic electrochemical synthesis of quinol-thioether conjugates: their implication in the serotonergic neurotoxicity of amphetamine derivatives]. / Synthèse électrochimique biomimétique de conjugués quinol-thioéthers: leur implication dans la neurotoxicité sérotoninergique de dérivés de l'amphétamine.

Injection of 3,4-methylenedioxyamphetamine (MDA) or 3,4-methylenedioxymethylamphetamine (MDMA or ecstasy) directly into the brain fails to reproduce the long-term effects observed after peripheral administration, implying an essential role for systemic metabolites in the development of toxicity. However, the precise identity of the metabolites participating in MDA and MDMA-mediated serotonergic neurotoxicity remains unclear: neither 3,4-alpha-methyldopamine, nor N-methyl-alpha-methyldopamine, major metabolites, produce neurotoxicity following peripheral administration. In vivo, these metabolites are oxidized to the corresponding orthoquinones, that readily react with protein and nonprotein sulphydryls including glutathione (GSH). The resulting quinol-thioether conjugates exhibit a variety of toxicological activities, which can be regulated by intramolecular cyclisation reactions that occur subsequent to oxidation. The ability of quinol-thioether conjugates to redox cycle and produce reactive oxygen species provides a rationale for the potential role of these metabolites in MDA and MDMA neurotoxicity. A biomimetic one-pot synthesis of 5-(GSH-S-yl)-N-Me-alpha-Me-DA involving addition of GSH to the electrogenerated orthoquinone species, is reported to evaluate its in vivo potential neurotoxicity.

Synthesis of novel orthoalkylaminophenol derivatives as potent neuroprotective agents in vitro.

A series of orthoalkylaminophenol derivatives was synthesized and tested in vitro with respect to their neuroprotective effect. Some of these compounds exhibited a potent antioxidant activity close to that of standard alpha-tocopherol.