Liquid chromatography combined with tandem mass spectrometry for the confirmation of sarafloxacin in catfish tissue.

A specific chromatographic LC/MS/MS assay is described for the confirmatory identification of residues of sarafloxacin, an arylfluoroquinolone antibacterial agent, in catfish tissue. This confirmatory method takes advantage of the specificity provided by sample preparation, liquid chromatography, and tandem mass spectrometry. This kind of multidimensional analysis is commonly used in environmental, pharmacokinetic, residue, and other studies. However, we demonstrate the addition of a previously unreported criterion, the use of ion ratio ranges from the tandem mass spectrometry (MS/MS) experiment as an aid in confirmation. Using the described method, we were able to achieve MS/MS product ion ratios with <7% variation during 1 day of analysis for over 25 injections. We believe the addition of this criterion will increase the scientific certainty of the confirmatory method.

The in vitro hepatic metabolism of ABT-418, a cholinergic channel activator, in rats, dogs, cynomolgus monkeys, and humans.

The metabolism of the cholinergic channel activator [3H]ABT-418 was studied in 9,000g supernatant (S-9) fractions and precision-cut tissue slices prepared from rat, dog, monkey, and human livers. In rat S-9 fractions and tissue slices, the lactam and trans N'-oxide were detected as major metabolites. The lactam was also the major metabolite in monkey and human S-9 fractions and tissue slices, although the rate of formation was greater in monkey (Vmax' of 428 vs. 103 pmol/min/mg S-9 protein). Trans N'-oxide was not detected in either species, but low levels of the cis N'-oxide were detected in tissue slice preparations from two human subjects. In contrast, trans ABT-418 N'-oxide was identified as a major metabolite in dog S-9 fractions (Vmax' of 266 pmol metabolite formed/min/mg S-9 protein) and tissue slices. Although identified as a minor metabolite in dog S-9 fractions, the lactam metabolite was shown to account for a sizeable proportion of the total radioactivity in the corresponding tissue slice preparations (22% of the total radioactivity at 12 hr); the rank order of lactam formation by the precision-cut liver slices was monkey > human > rat > or = dog. Evidence that N'-oxidation and C-oxidation (to lactam) of ABT-418 was mediated by liver microsomal flavin-containing mono-oxygenase (FMO) and cytochromes P-450 (CYPs), respectively, was obtained with the inhibitors thiobenzamide and clotrimazole. The involvement of cytosolic aldehyde oxidase (AO) was suggested by a significant correlation (r2 = 0.998, p < 0.01) between the observed rate of lactam formation and AO (N1-methylnicotinamide oxidase) activity in rat, dog, monkey, and human S-9 fractions; inhibition of lactam formation by the AO substrate N1-methylnicotinamide; and the lack of lactam formation in the absence of cytosol. Data indicate that the species-related differences in the hepatic metabolism of ABT-418 may be dependent on the relative levels and/or activity of FMO, CYP, and AO. In this regard, ABT-418 is very similar to nicotine. However, unlike nicotine, the N-demethylation of parent drug and the further products of lactam metabolism was not detected.

HPLC and PDMS analysis of cleavage products aid in the design of small, stable ANP analogues.

The degradation of a prototypical small analogue of atrial natriuretic peptide (ANP) has been studied using HPLC and mass spectrometric techniques. These studies revealed that removal of the N-terminal amino acid was the primary catabolic event in vitro. Based on this information the N-terminus was remanufactured to provide a family of more stable analogues. Additional stabilization was provided through modification of the C-terminal tripeptide. Through dramatically more stable in vitro, these new analogues do not appear to have longer in vivo half-lives.