Shon P. Neal scite author profile

Anabolic androgenic steroids (AAS) make up one of the most prevalent classes of performance-enhancing drugs banned by the World Anti-Doping Agency (WADA) due to the competitive advantage they can afford athletes. Mass spectrometry-based methods coupled with chromatographic separations have become the gold standard for AAS analysis because of the superior sensitivity and selectivity provided. However, emerging analytical techniques including ion mobility spectrometry (IMS) have been demonstrated in recent applications as a means to further characterize and identify potential unknowns while simultaneously delivering improved sensitivity by filtering noise. Herein we outline the next crucial steps in bringing IMS to the routine drug testing workflow by combining it with established chromatographic and mass spectrometry methods (i.e., LC−IM−MS) for the detection of AAS in human urine. In addition to robust measurement of collision cross sections which can be used for identification purposes, functional group microtrends provide a structural basis on which to elucidate the structure of future novel anabolic agents. Lastly, the developed workflow is tested by analysis of testosterone in a realistic matrix (human urine) and demonstrates a limit of detection of 524 pg/mL, which surpasses the WADA Minimum Required Performance Levels for anabolic steroids. This work is expected to pave the way toward routine incorporation of IMS into analytical drug testing workflows to augment both qualitative and quantitative measure of performance enhancing drugs in the future.

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Targeted glucocorticoid analysis using ion mobility-mass spectrometry (IM-MS)

Neal

Wilson

Velosa

et al. 2022

Journal of Mass Spectrometry and Advances in the Clinical Lab

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Improved Ion Mobility Separation and Structural Characterization of Steroids using Derivatization Methods

Velosa

Dunham

Rivera

et al. 2022

J. Am. Soc. Mass Spectrom.

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Steroids are an important class of biomolecules studied for their role in metabolism, development, nutrition, and disease. Although highly sensitive GC- and LC-MS/MS-based methods have been developed for targeted quantitation of known steroid metabolites, emerging techniques including ion mobility (IM) have shown promise in improved analysis and capacity to better identify unknowns in complex biological samples. Herein, we couple LC-IM-MS/MS with structurally selective reactions targeting hydroxyl and carbonyl functional groups to improve IM resolution and structural elucidation. We demonstrate that 1,1-carbonyldiimidazole derivatization of hydroxyl stereoisomer pairs such as testosterone/epitestosterone and androsterone/epiandrosterone results in increased IM resolution with ΔCCS > 15%. Additionally, performing this in parallel with derivatization of the carbonyl group by Girard’s Reagent P resulted in unique products based on relative differences in number of each functional group and C17 alkylation. These changes could be easily deciphered using the combination of retention time, collision cross section, accurate mass, and MS/MS fragmentation pattern. Derivatization by Girard’s Reagent P, which contains a fixed charge quaternary amine, also increased the ionization efficiency and could be explored for its potential benefit to sensitivity. Overall, the combination of these simple and easy derivatization reactions with LC-IM-MS/MS analysis provides a method for improved analysis of known target analytes while also yielding critical structural information that can be used for identification of potential unknowns.

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Zinc Ammonio-dodecaborates: Synthesis, Lewis Acid Strength, and Reactivity

et al. 2022

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Two series of zinc salts, [EtZn][A] and Zn[A]2, with weakly coordinating anions [A]− as counterions have been prepared, and their activities as catalysts for hydrosilylation reactions of 1-hexene, benzophenone, and acetophenone have been investigated. The counterions and per- and partially chlorinated 1-ammonio-closo-dodecaborate anions [Me3NB12Cl11]− [1]−, [Pr3NB12H5Cl6]− [2]−, [Bu3NB12H4Cl7]− [3]−, and [Hex3NB12H5Cl6]− [4]− were chosen as potential and more readily available alternatives to carborate anions such as [CHB11Cl11]− and [HexCB11Cl11]−. The basicity of anion [4]− was determined as being close to that of the triflimide anion [N(SO2CF3)2]−, and the fluoride ion affinities (FIAs) of compounds [EtZn][2] and Zn[2]2 are lower than those of the Lewis acids B(C6F5)3 and Zn[HexCB11Cl11]2. The higher anion basicity and the resulting lower Lewis acidity of the zinc centers result in low activity in 1-hexene hydrosilylation catalysis and only moderate activity in the hydrosilylation catalysis of benzophenone and acetophenone.

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Ion Mobility-Mass Spectrometry in Food and Environmental Chemistry

Neal

Chouinard

2022

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Shon P. Neal

Toward Routine Analysis of Anabolic Androgenic Steroids in Urine Using Ion Mobility-Mass Spectrometry

Targeted glucocorticoid analysis using ion mobility-mass spectrometry (IM-MS)

Improved Ion Mobility Separation and Structural Characterization of Steroids using Derivatization Methods

Zinc Ammonio-dodecaborates: Synthesis, Lewis Acid Strength, and Reactivity

Ion Mobility-Mass Spectrometry in Food and Environmental Chemistry

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