Corrole isomers: intrinsic gas-phase shapes via traveling wave ion mobility mass spectrometry and dissociation chemistries via tandem mass spectrometry

Fasciotti, Maíra; Gomes, Alexandre F.; Gozzo, Fábio C.; Iglesias, Bernardo A.; Sá, Gilberto F. de; Daroda, Romeu J.; Toganoh, Motoki; Furuta, Hiroyuki; Araki, Koji; Eberlin, Marcos N.

doi:10.1039/c2ob26209f

Cited by 19 publications

(15 citation statements)

References 42 publications

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“…Utilizing more polar drift‐gases could potentially influence almost every application area where structural isomers are being investigated by TWIM‐MS and improved R p‐p is required. Studies have already demonstrated the beneficial results in using CO 2 as the TWIM drift‐gas . Based on our findings, the use of more polarizable drift‐gases improves R p‐p considerably for the isomers that differ in electrostatic surface potential, whereas isomeric pairs which electrostatic surface potential is only subtly different, R p‐p is not significantly affected.…”

Section: Resultsmentioning

confidence: 99%

Baseline resolution of isomers by traveling wave ion mobility mass spectrometry: investigating the effects of polarizable drift gases and ionic charge distribution

et al. 2013

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We have studied the behavior of isomers and analogues by traveling wave ion mobility mass spectrometry (TWIM-MS) using drift-gases with varying masses and polarizabilities. Despite the reduced length of the cell (18 cm), a pair of constitutional isomers, N-butylaniline and para-butylaniline, with theoretical collision cross-section values in helium (ΩHe ) differing by as little as 1.2 Å(2) (1.5%) but possessing contrasting charge distribution, showed baseline peak-to-peak resolution (Rp-p ) for their protonated molecules, using carbon dioxide (CO2), nitrous oxide (N2O) and ethene (C2H4 ) as the TWIM drift-gas. Near baseline Rp-p was also obtained in CO2 for a group of protonated haloanilines (para-chloroaniline, para-bromoaniline and para-iodoaniline) which display contrasting masses and theoretical ΩHe , which differ by as much as 15.7 Å(2) (19.5%) but similar charge distributions. The deprotonated isomeric pair of trans-oleic acid and cis-oleic acid possessing nearly identical theoretical ΩHe and ΩN2 as well as similar charge distributions, remained unresolved. Interestingly, an inversion of drift-times were observed for the 1,3-dialkylimidazolium ions when comparing He, N2 and N2O. Using density functional theory as a means of examining the ions electronic structure, and He and N2-based trajectory method algorithm, we discuss the effect of the long-range charge induced dipole attractive and short-range Van der Waals forces involved in the TWIM separation in drift-gases of differing polarizabilities. We therefore propose that examining the electronic structure of the ions under investigation may potentially indicate whether the use of more polarizable drift-gases could improve separation and the overall success of TWIM-MS analysis.

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Section: Resultsmentioning

confidence: 99%

Baseline resolution of isomers by traveling wave ion mobility mass spectrometry: investigating the effects of polarizable drift gases and ionic charge distribution

et al. 2013

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“…In TWIM, ions are accumulated and periodically released into a stacked ring ion guide (T‐wave cell) where they drift under the action of a continuous train of transient voltage pulses applied to a pair of stacked ring electrodes that work as an ion mobility cell. We have used TWIM‐MS to separate and characterize geometrical isomers such as meta/para and cis/trans cationic ruthenates meso‐pyridylporphyrins, corrole isomers and isomeric disaccharides …”

Section: Introductionmentioning

confidence: 99%

“…[28,29] In TWIM, ions are accumulated and periodically released into a stacked ring ion guide (T-wave cell) where they drift under the action of a continuous train of transient voltage pulses applied to a pair of stacked ring electrodes that work as an ion mobility cell. We have used TWIM-MS to separate and characterize geometrical isomers such as meta/para and cis/trans cationic ruthenates meso-pyridylporphyrins, [30] corrole isomers [31] and isomeric disaccharides. [32] For glycosylated molecules, in which different and highly competitive coordinating sites are available for cation binding, several catiomers [3] with eventually similar cross sections and polarizabilities could be formed, and therefore, the determination of the site of cationization is particularly challenging.…”

Section: Introductionmentioning

confidence: 99%

Separation of glycosidic catiomers by TWIM‐MS using CO₂ as a drift gas

Bataglion

Souza²,

Heerdt

et al. 2015

J. Mass Spectrom.

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Traveling wave ion mobility mass spectrometry (TWIM-MS) is shown to be able to separate and characterize several isomeric forms of diterpene glycosides stevioside (Stv) and rebaudioside A (RebA) that are cationized by Na(+) and K(+) at different sites. Determination and characterization of these coexisting isomeric species, herein termed catiomers, arising from cationization at different and highly competitive coordinating sites, is particularly challenging for glycosides. To achieve this goal, the advantage of using CO2 as a more massive and polarizable drift gas, over N2, was demonstrated. Post-TWIM-MS/MS experiments were used to confirm the separation. Optimization of the possible geometries and cross-sectional calculations for mobility peak assignments were also performed.

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“…He, N 2 , or CO 2 ), referred to as collision cross section (CCS), under the influence of a weak electronic field . Hence, IM provides specific information on structural conformation and is therefore currently used in several research areas and applications with a wide range from low molecular weight compounds up to mega Dalton‐sized biological structures including the rapid detection of chemicals in waste water and air, peptide and protein structure determination, pharmaceutical compound analysis, and studies on crude oil …”

Section: Introductionmentioning

confidence: 99%

“…[26,27] Hence, IM provides specific information on structural conformation and is therefore currently used in several research areas and applications with a wide range from low molecular weight compounds up to mega Dalton-sized biological structures including the rapid detection of chemicals in waste water and air, peptide and protein structure determination, pharmaceutical compound analysis, and studies on crude oil. [28][29][30][31][32][33][34][35][36][37] In the present study, travelling-wave ion mobility spectrometry (TWIMS) with nitrogen as drift gas interfaced to a quadrupoletime-of-flight (QqTOF) mass spectrometer was used to generate information on the conjugation site of stanozolol glucuronides observed in post-administration urine samples and authentic doping control specimens. Therefore, drift times of five different but structurally related known AAS glucuronides were determined, corresponding CCSs were calculated by means of modelling software tools (ORCA and MOBCAL) employing the data set of B3LYP/6-31G, [38][39][40][41][42] and a calibration curve for AAS glucuronides was created.…”

Section: Introductionmentioning

confidence: 99%

Complementing the characterization of in vivo generated N‐glucuronic acid conjugates of stanozolol by collision cross section computation and analysis

Thevis

Dib

Thomas

et al. 2015

Drug Testing and Analysis

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Detailed structural information on metabolites serving as target analytes in clinical, forensic, and sports drug testing programmes is of paramount importance to ensure unequivocal test results. In the present study, the utility of collision cross section (CCS) analysis by travelling wave ion mobility measurements to support drug metabolite characterization efforts was tested concerning recently identified glucuronic acid conjugates of the anabolic-androgenic steroid stanozolol. Employing travelling-wave ion mobility spectrometry/quadrupole-time-of-flight mass spectrometry, drift times of five synthetically derived and fully characterized steroid glucuronides were measured and subsequently correlated to respective CCSs as obtained in silico to form an analyte-tailored calibration curve. The CCSs were calculated by equilibrium structure minimization (density functional theory) using the programmes ORCA with the data set B3LYP/6-31G and MOBCAL utilizing the trajectory method (TM) with nitrogen as drift gas. Under identical experimental conditions, synthesized and/or urinary stanozolol-N and O-glucuronides were analyzed to provide complementary information on the location of glucuronidation. Finally, the obtained data were compared to CCS results generated by the system's internal algorithm based on a calibration employing a polyalanine analyte mixture. The CCSs ΩN2 calculated for the five steroid glucuronide calibrants were found between 180 and 208 Å(2) , thus largely covering the observed and computed CCSs for stanozolol-N1'-, stanozolol-N2'-, and stanozolol-O-glucuronide found at values between 195.1 and 212.4 Å(2) . The obtained data corroborated the earlier suggested N- and O-glucuronidation of stanozolol, and demonstrate the exploit of ion mobility and CCS computation in structure characterization of phase-II metabolic products; however, despite reproducibly measurable differences in ion mobility of stanozolol-N1'-, N2'-, and O-glucuronides, the discriminatory power of the chosen CCS computation algorithm was found to be not appropriate to allow for accurate assignments of the two N-conjugated structures. Using polyalanine-based calibrations, significantly different absolute values were obtained for all CCSs, but due to a constant offset of approximately 45 Å(2) an excellent correlation (R(2) = 0.9997) between both approaches was observed. This suggests a substantially accelerated protocol when patterns of computed and polyalanine-based experimental data can be used for structure elucidations instead of creating individual analyte-specific calibration curves.

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Corrole isomers: intrinsic gas-phase shapes via traveling wave ion mobility mass spectrometry and dissociation chemistries via tandem mass spectrometry

Cited by 19 publications

References 42 publications

Baseline resolution of isomers by traveling wave ion mobility mass spectrometry: investigating the effects of polarizable drift gases and ionic charge distribution

Baseline resolution of isomers by traveling wave ion mobility mass spectrometry: investigating the effects of polarizable drift gases and ionic charge distribution

Separation of glycosidic catiomers by TWIM‐MS using CO₂ as a drift gas

Complementing the characterization of in vivo generated N‐glucuronic acid conjugates of stanozolol by collision cross section computation and analysis

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Corrole isomers: intrinsic gas-phase shapes via traveling wave ion mobility mass spectrometry and dissociation chemistries via tandem mass spectrometry

Cited by 19 publications

References 42 publications

Baseline resolution of isomers by traveling wave ion mobility mass spectrometry: investigating the effects of polarizable drift gases and ionic charge distribution

Baseline resolution of isomers by traveling wave ion mobility mass spectrometry: investigating the effects of polarizable drift gases and ionic charge distribution

Separation of glycosidic catiomers by TWIM‐MS using CO2 as a drift gas

Complementing the characterization of in vivo generated N‐glucuronic acid conjugates of stanozolol by collision cross section computation and analysis

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Separation of glycosidic catiomers by TWIM‐MS using CO₂ as a drift gas