BOOSTING SENSITIVITY IN TOP-DOWN PROTEIN STUDIES USING CYCLIC IMS-ENABLED WIDEBAND ENHANCEMENT

Posters | 2026 | Waters | ASMSInstrumentation
LC/MS, LC/MS/MS, LC/TOF, LC/HRMS, Ion Mobility
Industries
Proteomics
Manufacturer
Waters

Summary

Significance of the topic

The ability to characterize intact proteins and their post-translational modifications (PTMs) by top-down mass spectrometry depends critically on MS/MS sensitivity. For intact proteins, signal is dispersed across many product ions, multiple charge states and broad isotope envelopes, reducing per-ion intensity and limiting sequence coverage and confident PTM localization. Methods that increase MS/MS duty cycle and ion utilization therefore directly improve the depth and reliability of top-down analyses, particularly for low-efficiency fragmentation methods such as electron capture dissociation (ECD).

Objectives and overview of the study

This work reports the implementation and evaluation of Wideband Enhancement (WBE) on a Cyclic IMS P20 time-of-flight mass spectrometer to boost MS/MS sensitivity in top-down protein experiments. The study aimed to quantify sensitivity gains for both collision-induced dissociation (CID) and ECD across the mass range, demonstrate compatibility with ion mobility separation, and assess the impact on sequence coverage for small and medium-sized proteins (bovine ubiquitin and bovine carbonic anhydrase II). Experiments compared single-pass IMS, bypass IMS, and TOF-only acquisition with and without WBE.

Methods and used instrumentation

  • Samples: Bovine ubiquitin (~8.5 kDa) and bovine carbonic anhydrase II (~29 kDa) analyzed under denaturing conditions by direct infusion.
  • Instrument: Waters Cyclic IMS P20 mass spectrometer equipped with an electron capture dissociation cell; positive electrospray ionization (ESI) operation.
  • Fragmentation: Both CID and ECD MS/MS were used to generate complementary fragment ion series (b/y and c/z types).
  • Ion mobility modes: Single-pass mode (0.98 m cyclic travelling-wave separation) and bypass mode (minimal separation) were tested; multi-pass mobility acquisitions were also considered for enhanced separation.
  • Wideband Enhancement (WBE): Synchronization of ion packets exiting the IMS with the TOF pusher to maximize duty cycle for defined m/z windows, increasing the fraction of ions detected.
  • Data acquisition and processing: MassLynx v4.2 for acquisition; DriftScope, waters_connect and UNIFI peptide mapping workflows for visualization and sequence coverage analysis.

Main results and discussion

  • Sensitivity gains: WBE produced up to a 10-fold increase in fragment ion intensity for top-down MS/MS. Representative improvements include ~10× for low m/z fragments and ~8× for high m/z fragments in ubiquitin CID spectra.
  • ECD performance: Because ECD has lower intrinsic fragmentation efficiency than CID, WBE provided particularly pronounced benefits. For carbonic anhydrase II, ECD sequence coverage improved from 54% (WBE off) to 70% (WBE on) in bypass IMS mode, a ~15 percentage point gain, enabling denser c- and z-type ion series across the mass range.
  • IMS compatibility: WBE enables high-sensitivity MS/MS while retaining ion mobility separation. Bypass IMS combined with WBE yielded the highest sensitivity boost, but single-pass IMS with WBE also provided significant gains without sacrificing spectral resolution.
  • Practical spectral effects: WBE not only increased peak intensities but improved peak profiles and signal-to-noise, facilitating detection of low-abundance fragments and better coverage of isotopic clusters.

Benefits and practical applications

  • Enhanced top-down proteomics sensitivity: WBE increases the detectable fragment ion population, improving identification confidence and enabling detection of low-abundance proteoforms and PTMs.
  • Improved ECD utility: By amplifying low-efficiency ECD fragments, WBE makes electron-based dissociation more practical for larger proteins and more informative for backbone cleavage mapping.
  • Versatility with IMS: The approach preserves or complements ion mobility separation, so structural/shape information can be retained alongside improved MS/MS sensitivity.
  • Laboratory impact: Greater sensitivity allows reduced sample amounts, faster acquisition or higher throughput in targeted top-down workflows, beneficial for research and QA/QC applications.

Future trends and possibilities for use

  • LC–MS integration: Translating WBE gains from direct infusion into LC-coupled top-down workflows to improve chromatographic peak interrogation and proteoform profiling in complex samples.
  • Adaptive acquisition: Real-time control of WBE windows guided by mobility or precursor information to optimize duty cycle for dynamically changing m/z distributions.
  • Extension to other electron-based methods: Applying WBE concepts to ETD and hybrid electron-driven techniques to similarly boost sensitivity for complementary fragmentation channels.
  • Native and larger-protein analysis: Leveraging improved ion utilization to expand intact-protein coverage under native conditions and for higher-mass proteoforms.
  • Automation and AI: Combining WBE-enhanced data with automated interpretation and machine-learning tools to accelerate proteoform discovery and PTM localization.

Conclusion

Wideband Enhancement implemented on a Cyclic IMS P20 mass spectrometer markedly increases MS/MS sensitivity for top-down protein analysis, delivering up to 10× higher fragment ion signals while remaining compatible with ion mobility separation. The approach is especially valuable for electron-based fragmentation (ECD), where it substantially improves sequence coverage for larger proteins. WBE therefore provides a practical route to more comprehensive and confident intact-protein characterization in research and applied laboratory settings.

References

  1. Cui W, Rohrs HW, Gross ML. Top-down mass spectrometry: Recent developments, applications and perspectives. Analyst. 2011;136(19):3854–3864.
  2. Hoang C, Uritboonthai W, Hoang L, et al. Tandem Mass Spectrometry across Platforms. Analytical Chemistry. 2024;96(14):5478–5488.

Content was automatically generated from an orignal PDF document using AI and may contain inaccuracies.

Downloadable PDF for viewing
 

Similar PDF

Toggle
Increasing sensitivity in peptide-level studies; Cyclic ECD product ions
Increasing sensitivity in peptide-level studies; Cyclic ECD product ions Dale A. Cooper-Shepherd1, Isabella A. Jones1, Emma Marsden-Edwards1, Ramin Rabbani2 1Waters Corporation, Wilmslow, Cheshire, UK; 2Waters Corporation, Milford, MA, USA IMS-enabled Wideband Enhancement of CID and INTRODUCTION OPTIMIZATION OF CYCLIC IMS…
Key words
wbe, wbewideband, widebandenhancement, enhancementpeptide, peptidecyclic, cyclicecd, ecdmobility, mobilityedc, edcpusher, pusherion, ionions, ionscid, cidpeptides, peptidessensitivity, sensitivityproduct
DEVELOPMENT OF A MODIFIED CYCLIC IMS PLATFORM FOR ENHANCED BIOMOLECULE CHARACTERIZATION
DEVELOPMENT OF A MODIFIED CYCLIC IMS PLATFORM FOR ENHANCED BIOMOLECULE CHARACTERIZATION Bryan J. McCullough1, Dale A. Cooper-Shepherd1, Darren Hewitt1, David Harker1 & Emma Marsden-Edwards1 1. Waters Corporation, Stamford Avenue, Altrincham Rd., Wilmslow, UK INTRODUCTION Tof duty cycle is inherently limited…
Key words
wbe, wbeciu, ciudeclustering, declusteringdfd, dfdions, ionscyclic, cyclicion, ionselectively, selectivelywideband, widebanddevice, devicestepwave, stepwavepusher, pushermobility, mobilityoff, offmass
Developing a declustering ion guide and Cyclic IMS-enabled Wideband Enhancement for native top-down studies
Developing a declustering ion guide and Cyclic IMS-enabled Wideband Enhancement for native top-down studies Isabella A. Jones1, Dale A. Cooper-Shepherd2, Emma Marsden-Edwards2 1University of Birmingham, Birmingham, United Kingdom; 2Waters Corporation, Wilmslow, United Kingdom INTRODUCTION • • • • • •…
Key words
bacteriorhodopsin, bacteriorhodopsinwbe, wbenative, nativeims, imsdeclustering, declusteringwideband, widebandcyclic, cyclicenhancement, enhancementpackets, packetstop, topdown, downnistmab, nistmabregion, regionduty, dutyhalobacterium
Waters Cyclic IMS P20 Mass Spectrometer
Waters Cyclic IMS P20 Mass Spectrometer
2026|Waters|Brochures and specifications
Waters Cyclic IMS P20 Mass Spectrometer Insight—revealed, not inferred. Insight— revealed, not inferred Biological systems are inherently complex, and answering today’s research questions requires tools that can reveal that complexity with clarity. The Waters™ Cyclic™ IMS P20 Mass Spectrometer enables…
Key words
wbe, wbedfd, dfdion, ionmobility, mobilityconformational, conformationaldeclustering, declusteringnative, nativeciu, ciucyclic, cyclicpusher, pusherprotein, proteinconfident, confidentmolecular, molecularactivation, activationelectrodes
Other projects
GCMS
ICPMS
Follow us
FacebookX (Twitter)LinkedInYouTube
More information
WebinarsAbout usContact usTerms of use
LabRulez s.r.o. All rights reserved. Content available under a CC BY-SA 4.0 Attribution-ShareAlike