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Frequency chasing of individual megadalton ions in an Orbitrap analyser improves precision of analysis in single-molecule mass spectrometry

Tobias P. Wörner, Konstantin Aizikov, Joost Snijder, Kyle L. Fort, Alexander Makarov, Albert J. R. Heck

2022Nature Chemistry57 citationsDOIOpen Access PDF

Abstract

To enhance the performance of charge-detection mass spectrometry, we investigated the behaviour of macromolecular single ions on their paths towards and within the Orbitrap analyser. Ions with a mass beyond one megadalton reach a plateau of stability and can be successfully trapped for seconds, travelling a path length of multiple kilometres, thereby enabling precise mass analysis with an effective resolution of greater than 100,000 at a mass-to-charge ratio of 35,000. Through monitoring the frequency of individual ions, we show that these high-mass ions, rather than being lost from the trap, can gradually lose residual solvent molecules and, in rare cases, a single elementary charge. We also demonstrate that the frequency drift of single ions due to desolvation and charge stripping can be corrected, which improves the effective ion sampling 23-fold and gives a twofold improvement in mass precision and resolution.

Topics & Concepts

OrbitrapChemistryIonMass spectrometryAnalyserResolution (logic)Fragmentation (computing)Analytical Chemistry (journal)MoleculeQuadrupole ion trapIon-mobility spectrometryIon trapChromatographyArtificial intelligenceOrganic chemistryOperating systemComputer scienceMass Spectrometry Techniques and ApplicationsIon-surface interactions and analysisAnalytical chemistry methods development
Frequency chasing of individual megadalton ions in an Orbitrap analyser improves precision of analysis in single-molecule mass spectrometry | Litcius