Abstract
Bile acids are steroid compounds involved in biological mechanisms of neurodegenerative diseases making them potential biomarkers for diagnosis or treatment. These compounds exist as structural and conformational isomers, which hinder distinguishing them in physiological processes. We aimed to develop tandem mass spectrometry-ion mobility spectrometry (MS/MS-IMS) methodologies to explore and understand the behaviour of isomeric steroids in the gas-phase and rapidly separate them. Unlike previously published ion mobility data, various isomers were investigated in mixtures to better mimic complex (pre-) clinical samples. The experimental collision cross sections (CCS)s were compared to the theoretical CCS values for an in-depth analysis of isomeric ions' behaviour in the gas-phase. Based on density-functional theory, we identified the impact of adduct positioning on the 3D conformation of enantiomers, diastereomers and structural isomers. The curling of the large side chains hedged the small differences among the isomers and lowered the CCS values. On the other hand, fragmenting off the identical side branches as well as imposing the bending of the steroid ring resulted in ion mobility differentiation. Careful data evaluation revealed the tendency of isomers to form homo-cluster in the mixture solutions and assist the separation. Our fundamental and experimental findings enable the ion mobility separation of isomeric steroids to be predicted. The introduced rapid and optimal MS/MS-IMS analytical methodology can be applied to distinguish isomeric bile acids both in a solution and potentially in patients' tissue samples, and consequently, reveal their molecular pathways.
Original language | English |
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Article number | 339617 |
Number of pages | 8 |
Journal | Analytica Chimica Acta |
Volume | 1200 |
DOIs | |
Publication status | Published - 1 Apr 2022 |
Keywords
- Humans
- Ion Mobility Spectrometry/methods
- Ions/chemistry
- Isomerism
- Steroids
- Tandem Mass Spectrometry/methods
- Bile acids
- Gas-phase molecular ion
- Collision cross section
- Traveling wave ion mobility
- MOLECULES
- BIOMARKERS
- Ion mobility
- Density functional theory
- BILE-ACIDS
- SPECTROMETRY