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Characterization of Elusive Reaction Intermediates Using Infrared Ion Spectroscopy: Application to the Experimental Characterization of Glycosyl Cations

Floor ter Braak, Hidde Elferink, Kas J. Houthuijs, Jos Oomens, Jonathan Martens, Thomas J. Boltje

2022Accounts of Chemical Research35 citationsDOIOpen Access PDF

Abstract

1-like pathways are more challenging to investigate because the glycosyl cation intermediates involved are highly reactive. The highly reactive nature of glycosyl cations complicates their characterization because they have a short lifetime and rapidly equilibrate with the corresponding contact ion pair. To overcome this hurdle and enable the study of glycosyl cation stability and structure, they can be generated in a mass spectrometer in the absence of a solvent and counterion in the gas phase. The ease of formation, stability, and fragmentation of glycosyl cations have been studied using mass spectrometry (MS). However, MS alone provides little information about the structure of glycosyl cations. By combining mass spectrometry (MS) with infrared ion spectroscopy (IRIS), the determination of the gas-phase structures of glycosyl cations has been achieved. IRIS enables the recording of gas-phase infrared spectra of glycosyl cations, which can be assigned by matching to reference spectra predicted from quantum chemically calculated vibrational spectra. Here, we review the experimental setups that enable IRIS of glycosyl cations and discuss the various glycosyl cations that have been characterized to date. The structure of glycosyl cations depends on the relative configuration and structure of the monosaccharide substituents, which can influence the structure through both steric and electronic effects. The scope and relevance of gas-phase glycosyl cation structures in relation to their corresponding condensed-phase structures are also discussed. We expect that the workflow reviewed here to study glycosyl cation structure and reactivity can be extended to many other reaction types involving difficult-to-characterize ionic intermediates.

Topics & Concepts

SN2 reactionChemistryReactive intermediateGlycosylReaction intermediateSN1 reactionOxocarbeniumGlycosylationReaction mechanismCarbocationComputational chemistryStereoselectivityCombinatorial chemistryCounterionIonPhotochemistryOrganic chemistryCatalysisNucleophileBiochemistryCarbohydrate Chemistry and SynthesisMass Spectrometry Techniques and ApplicationsGlycosylation and Glycoproteins Research
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