Using differential mobility spectrometry to measure ion solvation: an examination of the roles of solvents and ionic structures in separating quinoline-based drugs

Liu, Chang; Blanc, J. C. Yves Le; Shields, Jefry; Janiszewski, John; Ieritano, Christian; Ye, Gene F.; Hawes, Gillian F.; Hopkins, W. Scott; Campbell, J. Larry

doi:10.1039/c5an00842e

Cited by 54 publications

(81 citation statements)

References 52 publications

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“…How could these sites of protonation influence the DMS separation (or lack thereof) for the glycopeptides studied here? For the case of the separated doubly protonated species, the more negative CV shift by the MUC5AC-13 isomer suggests that it binds more strongly with the acetonitrile vapor added to the DMS cell than does the MUC5AC-3 isomer [34][35][36]. When considering the structural variation between isomers that could cause such a CV shift, the presence of possible intramolecular hydrogen bonds (IMHBs) in the MUC5AC-3 isomer that internally solvate a site of protonation could be proposed (vide infra).…”

Section: Separation Of Isomeric Glycopeptides By Dms Can Be Charge Stmentioning

confidence: 94%

Analyzing Glycopeptide Isomers by Combining Differential Mobility Spectrometry with Electron- and Collision-Based Tandem Mass Spectrometry

Campbell¹,

Baba²,

Liu³

et al. 2017

J. Am. Soc. Mass Spectrom.

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Differential mobility spectrometry (DMS) has been employed to separate isomeric species in several studies. Under the right conditions, factors such as separation voltage, temperature, the presence of chemical modifiers, and residence time can combine to provide unique signal channels for isomeric species. In this study, we examined a set of glycopeptide isomers, MUC5AC-3 and MUC5AC-13, which bear an N-acetyl-galactosamine (GalNAc) group on either threonine-3 or threonine-13. When analyzed as a mixture, the resulting MS and MS/MS spectra yield fragmentation patterns that cannot discern these convolved species. However, when DMS is implemented during the analysis of this mixture, two features emerge in the DMS ionogram representing the two glycopeptide isomers. In addition, by locking in DMS parameters at each feature, we could observe several low intensity CID fragments that contain the GalNAc functionality-specific amino acid residues - identifying the DMS separation of each isomer without standards. Besides conventional CID MS/MS, we also implemented electron-capture dissociation (ECD) after DMS separation, and clearly resolved both isomers with this fragmentation method, as well. The electron energy used in these ECD experiments could be tuned to obtain maximum sequence coverage for these glycopeptides; this was critical as these ions were present as doubly protonated species, which are much more difficult to fragment efficiently via electron-transfer dissociation (ETD). Overall, the combination of DMS with electron- or collision-based MS/MS methods provided enhanced separation and sequence coverage for these glycopeptide isomers. Graphical Abstract ᅟ.

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Section: Separation Of Isomeric Glycopeptides By Dms Can Be Charge Stmentioning

confidence: 94%

Analyzing Glycopeptide Isomers by Combining Differential Mobility Spectrometry with Electron- and Collision-Based Tandem Mass Spectrometry

Campbell¹,

Baba²,

Liu³

et al. 2017

J. Am. Soc. Mass Spectrom.

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“…The development of FAIMS science since the introduction of these ion types in early work by Guevremont has brought forward a deeper understanding and re‐evaluation of these definitions in several aspects. First, all “ion types” are actually “ion‐gas pair” types—the same ions can assume different types in different gases based upon the ion/molecule interactions between these species (Barnett et al, ; Levin et al, ; Campbell, Zhu, & Hopkins, ; Liu et al, ; Liu et al, ). Generally, increasing the mass and polarizability of gas molecules shifts ions from type C to B to A.…”

Section: Reporting Ion Mobility Measurementsmentioning

confidence: 99%

Recommendations for reporting ion mobility Mass Spectrometry measurements

Gabelica

Shvartsburg

Afonso

et al. 2019

Mass Spectrometry Reviews

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Here we present a guide to ion mobility mass spectrometry experiments, which covers both linear and nonlinear methods: what is measured, how the measurements are done, and how to report the results, including the uncertainties of mobility and collision cross section values. The guide aims to clarify some possibly confusing concepts, and the reporting recommendations should help researchers, authors and reviewers to contribute comprehensive reports, so that the ion mobility data can be reused more confidently. Starting from the concept of the definition of the measurand, we emphasize that (i) mobility values ( K 0 ) depend intrinsically on ion structure, the nature of the bath gas, temperature, and E / N ; (ii) ion mobility does not measure molecular surfaces directly, but collision cross section (CCS) values are derived from mobility values using a physical model; (iii) methods relying on calibration are empirical (and thus may provide method‐dependent results) only if the gas nature, temperature or E / N cannot match those of the primary method. Our analysis highlights the urgency of a community effort toward establishing primary standards and reference materials for ion mobility, and provides recommendations to do so. © 2019 The Authors. Mass Spectrometry Reviews Published by Wiley Periodicals, Inc.

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“…Many studies have been carried out to examine the fundamental aspects of ion separation under DMS conditions. [20][21][22][23][24] The effects of the gas modifier and other experimental conditions on the compensation voltage (CoV) of different analyte ions have been extensively studied. 25,26 The CoV shift of the analyte ions has been shown to correlate well with the square root of the inverse of the reduced mass of the "modifierclustered" analyte ions 27 and the Gibbs free energy for the cluster formation.…”

mentioning

confidence: 99%

“…25,26 The CoV shift of the analyte ions has been shown to correlate well with the square root of the inverse of the reduced mass of the "modifierclustered" analyte ions 27 and the Gibbs free energy for the cluster formation. 23,28 The amino acid sequence of the peptide used in this study was derived from one of the tryptic digested fragments of the Arginine Deiminase (ARD) protein and was modified with galactose (Gal), glucose (Glc) and mannose (Man) at the threonine residue to give EIDYIT (Gal)PAR, EIDYIT (Glc)PAR and EIDYIT (Man)PAR, respectively. These glycopeptides were custom-synthesized commercially (RoYo Biotech Co., Ltd, Shanghai, China) and were used without further purification.…”

mentioning

confidence: 99%

Fine adjustment of gas modifier loadings for separation of epimeric glycopeptides using differential ion mobility spectrometry mass spectrometry

Chen

et al. 2020

Rapid Comm Mass Spectrometry

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Using differential mobility spectrometry to measure ion solvation: an examination of the roles of solvents and ionic structures in separating quinoline-based drugs

Cited by 54 publications

References 52 publications

Analyzing Glycopeptide Isomers by Combining Differential Mobility Spectrometry with Electron- and Collision-Based Tandem Mass Spectrometry

Analyzing Glycopeptide Isomers by Combining Differential Mobility Spectrometry with Electron- and Collision-Based Tandem Mass Spectrometry

Recommendations for reporting ion mobility Mass Spectrometry measurements

Fine adjustment of gas modifier loadings for separation of epimeric glycopeptides using differential ion mobility spectrometry mass spectrometry

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