Application of liquid chromatography-mass spectrometry(n) analyses to the characterization of novel glyburide metabolites formed in vitro.

The application of bench-top ion-trap atmospheric pressure ionization mass spectrometry in the characterization of in vitro metabolites of glyburide is discussed. The metabolites formed in vitro by rat, dog, monkey and human liver microsomes were separated by reversed-phase high-performance liquid chromatography (HPLC) and characterized by mass spectrometry (MS)n experiments. The utility of data dependent MS1-MS2-MS3 analyses, where the mass spectrometer makes "real-time" decisions about the experiment to be performed, are described using the characterization of two novel metabolites of glyburide as an example. The metabolite profiles from each species were similar. Six cyclohexyl hydroxylation products were detected, as well as two novel monooxygenation products formed via hydroxylation of the ethyl chain at the benzylic position, and alpha to the amide nitrogen. The ion-trap with electrospray ionization proved to be a sensitive and reliable HPLC detection system that provided important chemical structure information.

Drug quantitation on a benchtop liquid chromatography-tandem mass spectrometry system.

The specificity and selectivity of LC-MS-MS is illustrated to explain why LC-MS-MS has become the method of choice for quantitation within the pharmaceutical industry. Two assays are described that demonstrate the facility with which new ion trap technology can utilize the selectivity and sensitivity of LC-MS-MS to quantitate trace level components within complex matrices, in particular human plasma. One assay undergoes a validation procedure and demonstrates the utility of this new technology for drug quantitation within a regulated environment.