Metabolic Identification Based on Proposed Mass Fragmentation Pathways of the Anabolic Steroid Bolasterone by Gas Chromatography Tandem Mass Spectrometry.
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引用次数: 0
Abstract
Bolasterone (7α,17α-dimethyl-androsta-4-en-17β-ol-3-one) was registered on the World Anti-Doping Agency's Prohibited list of substances. This study was aimed at evaluating the metabolism of bolasterone through in vitro (liver microsomes) and in vivo (rat urine) experiments to propose mass fragmentation pathways of the metabolites by gas chromatography-quadrupole tandem mass spectrometry (GC-EI-MS/MS). Their plausible chemical structures were suggested based on their fragmentation pathways to overcome the lack of available authentic standards. A total of 12 metabolites (5 mono-hydroxylated M1 to M5 and 7 di-hydroxylated M6 to M12) after trimethylsilylation were observed. Key diagnostic ions included m/z 403 (mono-hydroxylated) and m/z 491 (di-hydroxylated) with m/z 143, indicating an intact D ring (M1 to M5, M7, M9, M10, M11). Hydroxylation at the D ring (M6, M12) was characterized by ions m/z 231 or 219. Hydroxylation at the A (M5, M7) or B (M2/M3, M10) rings corresponded to m/z 281 and hydroxylation at C12 of the C ring (M4, M10) was indicated by m/z 285. Based on the comparison with bolasterone analogues such as testosterone and methyltestosterone and the interpretation of fragmentation pathways, the mono-hydroxylation metabolites M1 (at C11), M2/M3 (at C6), M4 (at C12), M5 (at C2), and di-hydroxylation metabolites M6 (at C11 and C16), M7 (at C2 and C11), M10 (at C6 and C12), and M12 (at C12 and C16) were proposed. The hydroxylation sites of M8, M9, and M11 could not be determined. This data can be useful for identifying hydroxylated metabolites by interpreting mass spectra of anabolic steroids with no standards available.
期刊介绍:
As the incidence of drugs escalates in 21st century living, their detection and analysis have become increasingly important. Sport, the workplace, crime investigation, homeland security, the pharmaceutical industry and the environment are just some of the high profile arenas in which analytical testing has provided an important investigative tool for uncovering the presence of extraneous substances.
In addition to the usual publishing fare of primary research articles, case reports and letters, Drug Testing and Analysis offers a unique combination of; ‘How to’ material such as ‘Tutorials’ and ‘Reviews’, Speculative pieces (‘Commentaries’ and ‘Perspectives'', providing a broader scientific and social context to the aspects of analytical testing), ‘Annual banned substance reviews’ (delivering a critical evaluation of the methods used in the characterization of established and newly outlawed compounds).
Rather than focus on the application of a single technique, Drug Testing and Analysis employs a unique multidisciplinary approach to the field of controversial compound determination. Papers discussing chromatography, mass spectrometry, immunological approaches, 1D/2D gel electrophoresis, to name just a few select methods, are welcomed where their application is related to any of the six key topics listed below.
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