Roland F. Staack

Chemistry, pharmacology, toxicology, and hepatic metabolism of Designer drugs of the amphetamine (ecstasy), piperazine, and pyrrolidinophenone types:A synopsis

Abstract: Designer drugs of the amphetamine type (eg, MDMA, MDEA, MDA), of the new benzyl or phenyl piperazine type (eg, BZP, MDBP, mCPP, TFMPP, MeOPP), or of the pyrrolidinophenone type (eg, PPP, MOPPP, MDPPP, MPPP, MPHP) have gained popularity and notoriety as rave drugs. These drugs produce feelings of euphoria and energy and a desire to socialize. Although in the corresponding drug scene designer drugs have the reputation of being safe, studies in rats and primates in combination with human epidemiologic investigations indicate potential risks to humans. Thus, a variety of adverse effects have been associated with the use/abuse of this class of drugs in humans, including a life-threatening serotonin syndrome, hepatotoxicity, neurotoxicity, and psychopathology. Metabolites were suspected to contribute to some of the toxic effects. Therefore, knowledge of the metabolism is a prerequisite for toxicologic risk assessment. The metabolic pathways, the involvement of cytochrome P450 isoenzymes in the main pathways, and their roles in hepatic clearance are described for designer drugs of different groups. In summary, polymorphically expressed CYP2D6 was the major enzyme catalyzing the major metabolic steps of the studied piperazine-and pyrrolidinophenone-derived designer drugs. However, it cannot be concluded at the moment whether this genetic polymorphism is of clinical relevance.

Platform switching from ELISA to Gyrolab™: a novel generic reagent omits the need to change critical reagents

During development of biotherapeutics, availability of specific assay reagents is usually limited. The possibility to switch from one ligand binding assay technology to another, while using the same reagents, would be desirable. Here, we report on an Alexa647(®)-labeled monoclonal antibody against digoxigenin (mAb-Alexa647(®)) that enables the detection of digoxigenylated analyte-specific ELISA reagents by Gyrolab(™). In an analysis of non-monoclonal antibody (mAb) and mAb drugs, this approach maintained the dynamic range, accuracy and precision of the standard Gyrolab™ approach using analyte-specific Alexa647(®)-labeled Ab. In a rat PK study, results of our approach, standard Gyrolab™ and ELISA were comparable, with difference values within the incurred sample reanalysis acceptance criteria. Therefore, mAb-Alexa647(®) enables an easy switch between ELISA and Gyrolab™, providing an effective way to benefit from both platforms.