Browsing by Subject "Ion mobility spectrometry"

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    AutoCCS: automated collision cross-section calculation software for ion mobility spectrometry-mass spectrometry
    (Oxford University Press, 2021) Lee, Joon-Yong; Bilbao, Aivett; Conant, Christopher R.; Bloodsworth, Kent J.; Orton, Daniel J.; Zhou, Mowei; Wilson, Jesse W.; Zheng, Xueyun; Webb, Ian K.; Li, Ailin; Hixson, Kim K.; Fjeldsted, John C.; Ibrahim, Yehia M.; Payne, Samuel H.; Jansson, Christer; Smith, Richard D.; Metz, Thomas O.; Chemistry and Chemical Biology, School of Science
    Motivation: Ion mobility spectrometry (IMS) separations are increasingly used in conjunction with mass spectrometry (MS) for separation and characterization of ionized molecular species. Information obtained from IMS measurements includes the ion's collision cross section (CCS), which reflects its size and structure and constitutes a descriptor for distinguishing similar species in mixtures that cannot be separated using conventional approaches. Incorporating CCS into MS-based workflows can improve the specificity and confidence of molecular identification. At present, there is no automated, open-source pipeline for determining CCS of analyte ions in both targeted and untargeted fashion, and intensive user-assisted processing with vendor software and manual evaluation is often required. Results: We present AutoCCS, an open-source software to rapidly determine CCS values from IMS-MS measurements. We conducted various IMS experiments in different formats to demonstrate the flexibility of AutoCCS for automated CCS calculation: (i) stepped-field methods for drift tube-based IMS (DTIMS), (ii) single-field methods for DTIMS (supporting two calibration methods: a standard and a new enhanced method) and (iii) linear calibration for Bruker timsTOF and non-linear calibration methods for traveling wave based-IMS in Waters Synapt and Structures for Lossless Ion Manipulations. We demonstrated that AutoCCS offers an accurate and reproducible determination of CCS for both standard and unknown analyte ions in various IMS-MS platforms, IMS-field methods, ionization modes and collision gases, without requiring manual processing. Availability and implementation: https://github.com/PNNL-Comp-Mass-Spec/AutoCCS. Supplementary information: Supplementary data are available at Bioinformatics online. Demo datasets are publicly available at MassIVE (Dataset ID: MSV000085979).
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    Measurement and Theory of Gas-Phase Ion Mobility Shifts Resulting from Isotopomer Mass Distribution Changes
    (American Chemical Society, 2021) Harrilal, Christopher P.; Gandhi, Viraj D.; Nagy, Gabe; Chen, Xi; Buchanan, Michael G.; Wojcik, Roza; Conant, Christopher R.; Donor, Micah T.; Ibrahim, Yehia M.; Garimella, Sandilya V.B.; Smith, Richard D.; Larriba-Andaluz, Carlos; Mechanical and Energy Engineering, School of Engineering and Technology
    The unanticipated discovery of recent ultra-high-resolution ion mobility spectrometry (IMS) measurements revealing that isotopomers─compounds that differ only in the isotopic substitution sites─can be separated has raised questions as to the physical basis for their separation. A study comparing IMS separations for two isotopomer sets in conjunction with theory and simulations accounting for ion rotational effects provides the first-ever prediction of rotation-mediated shifts. The simulations produce observable mobility shifts due to differences in gas-ion collision frequency and translational-to-rotational energy transfer. These differences can be attributed to distinct changes in the moment of inertia and center of mass between isotopomers. The simulations are in broad agreement with the observed experiments and consistent with relative mobility differences between isotopomers. These results provide a basis for refining IMS theory and a new foundation to obtain additional structural insights through IMS.