A Sensitive LC-MS/MS Assay for the Quantification of Methadone and its Metabolites in Dried Blood Spots: Comparison With Plasma.

INTRODUCTION: Methadone, a synthetic narcotic, is widely used both in adults and children for pain control and as a replacement drug in opioid use disorder to prevent craving and withdrawal. To support clinical pharmacokinetic trials in neonates, infants, and children, the authors developed and validated a novel, automated, highly sensitive liquid chromatography-electrospray-tandem mass spectrometry ionization (LC-ESI-MS/MS) method for the quantification of methadone and its metabolites, 2-ethylidene-1,5-dimethyl-3,3-diphenylpyrrolidine (EDDP) and 2-ethyl-5-methyl-3,3-diphenylpyraline (EMDP), in samples collected as dried blood spots. METHODS: Blood was spiked with different concentrations of methadone, EDDP, and EMDP, and blood drops were applied to filter paper cards. Punches of 6.4 mm were removed from the cards, and 600 µL of protein precipitation solution (methanol/0.2M ZnSO4, 7:3, vol/vol) containing the internal standards (methadone-d9 and EDDP-d5) at a concentration of 1 mcg/L was added. The extracts were analyzed using LC-ESI-MS/MS in combination with online extraction. The mass spectrometer was run in the positive multiple reaction monitoring mode, and the total run time was 3.2 minutes. RESULTS: For the dried blood spots, the assay has a lower limit of quantification of 0.1 mcg/L for methadone, EDDP, and EMDP. The range of reliable response for methadone for the ion transition m/z = 310.2→265.1 was 0.1-100 mcg/L and for the ion transition m/z = 310.2→223.1 5-1000 mcg/L. For EDDP, on the range of reliable response for the ion transition, m/z = 278.2→234.3 was 0.1-100 mcg/L and for the ion transition m/z = 278.2→186.1 5-1000 mcg/L. The calibration range for EMDP was 0.1-100 mcg/L. Accuracy (85%-115%) and imprecision (<15%) met predefined acceptance criteria. DISCUSSION: This assay allows for the measurement of small volume blood samples without the need for an intravenous blood draw, and thus, it is suitable for pharmacokinetics studies and therapeutic drug monitoring in pediatric patients.

Temsirolimus metabolic pathways revisited.

Temsirolimus, a derivative of sirolimus, exhibits potent antitumor properties. It was the goal of this study to identify yet unknown temsirolimus metabolites generated after incubation with human liver microsomes. Previously, 23-hydroxy-, 24-hydroxy, 12-hydroxy, hydroxy-piperidine and 27-O-desmethyl temsirolimus had been described.Metabolite structures were identified using high-resolution mass spectrometry, MS/iontrap (MSn) and comparison of fragmentation patterns of the metabolites with those of temsirolimus and other known sirolimus derivatives. Moreover, enzyme kinetic parameters of temsirolimus metabolite formation as well as the contribution of individual recombinant cytochrome P450 (CYP) enzymes to temsirolimus metabolism were investigated.Human liver microsomes mainly hydroxylated and/or demethylated temsirolimus. The structures of the following metabolites were identified: O-demethylated metabolites: 39-O-desmethyl, 16-O-desmethyl and 27-O-desmethyl temsirolimus; hydroxylated metabolites: hydroxy piperidine temsirolimus, 11-hydroxy, 12-hydroxy, 14-hydroxy, 23-hydroxy, 24-hydroxy, 25-hydroxy, 45/46-hydroxy and 49-hydroxy temsirolimus; demethylated-hydroxylated metabolites: 16-O-desmethyl, 24-hydroxy; 16-O-desmethyl, 23-hydroxy and 16-O-desmethyl 46-hydroxy temsirolimus; didemethylated metabolite: 27,39-O-didesmethyl temsirolimus; and dihydroxylated metabolite: 12,24-dihydroxy temsirolimus. It was confirmed that CYP3A4 represents the predominant enzyme responsible for temsirolimus metabolism. Moreover, CYP3A5 as well as CYP2C8 also showed significant activities especially resulting in the formation of 27-O-desmethyl, 25-hydroxy and hydroxy-piperidine temsirolimus.It is concluded that temsirolimus is metabolized to more than 20 metabolites, not counting metabolism via the sirolimus pathway. Eighteen of these metabolites could be structurally identified using ion trap MSn and high-resolution mass spectrometry. Moreover, the present study showed that, in addition to CYP3A4, metabolism via CYP3A5 and CYP2C8 also represent significant metabolic pathways.

A High-throughput HPLC-MS/MS Assay for the Detection, Quantification and Simultaneous Structural Confirmation of 136 Drugs and Metabolites in Human Urine.

BACKGROUND: Because of its superior sensitivity and specificity, multianalyte high-performance liquid chromatography coupled with tandem mass spectrometry has become the gold standard in clinical toxicology. Although several qualitative and quantitative liquid chromatography coupled with tandem mass spectrometry assays on various mass spectrometry platforms have been described in the literature, most methods either analyze only a limited number of compounds and/or require tedious and time-consuming sample preparation. METHODS: A major challenge in urine toxicology screening is the minimization of false-negative and false-positive results. This was addressed by screening for a comprehensive panel of 136 compounds of importance for pain and drug addiction clinics, using high-end, high-sensitivity, fast-scanning mass spectrometry in combination with simultaneous structural confirmation based on ion ratios. The assay was validated and successfully participated in proficiency challenges. RESULTS: The assay met all predefined acceptance criteria. The lower limit of quantifications ranged from 10 to 100 ng/mL. Interday trueness and imprecisions ranged from 73.8% to 116.2% and 2.4%-20.0%, respectively. The total assay run time was 10 minutes. CONCLUSIONS: We developed and successfully validated a robust, sensitive, and specific liquid chromatography coupled with tandem mass spectrometry-based urine toxicology screening platform that allows for the addition of drugs to quickly adjust to new clinical needs. To date, more than 3000 clinical samples have successfully been analyzed. Our results also indicated that such a quantitative multianalyte assay is pushing against the limits of current fast-scanning MS/MS instrumentation and that the number of analytes and their internal standards must be balanced with acceptable sensitivity, reproducibility, structural confirmation, and the ability to reliably quantify, all of which was achieved.