Precursor and Product Ion Mobility and Collision Cross Section Determination by Travelling Wave Cyclic Ion Mobility – Mass Spectrometry

Posters | 2026 | Waters | ASMSInstrumentation

LC/MS, LC/MS/MS, Ion Mobility, LC/TOF, LC/HRMS

Industries

Food & Agriculture, Pharma & Biopharma, Environmental

Manufacturer

Waters

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Summary

Importance of the topic

Ion mobility–mass spectrometry (IM-MS) provides an orthogonal separation dimension that is highly valuable for structural characterization of small molecules and isomers in pharmaceutical, environmental, natural product and toxicology applications. Travelling-wave cyclic ion mobility (cIM) extends separation pathlength and resolution, enabling measurement of collision cross section (CCS) for both precursor and product ions. Combining CCS measurements with chromatographic retention, high-resolution mass-to-charge (m/z) and in-silico fragmentation enhances confidence in compound identification where conventional MS/MS alone cannot resolve positional or structural isomers.

Objectives and overview of the study

The study evaluated the capabilities of a travelling-wave cyclic ion mobility–mass spectrometry platform for:

Measuring CCS of intact precursor ions and of product (fragment) ions.
Resolving and discriminating isomeric compounds (e.g., linear vs branched PFOS isomers; flavonoid positional isomers).
Developing workflows for processing and reviewing multidimensional datasets that combine m/z, retention time, CCS and intensity.
Demonstrating integration with in-silico fragmentation prediction to annotate product ions and generate CCS fingerprints for small molecules relevant to pharmaceuticals and environmental analysis.

Methodology

Samples and applications investigated:

Natural-product flavonoid isomers (isoorientin, isovitexin, orientin, vitexin).
System suitability mixture including common MS standards (acetaminophen, caffeine, sulfaguanidine, sulfadimethoxine, Val-Tyr-Val, verapamil, reserpine, terfenadine, Leu-enkephalin).
Pharmaceutical compounds (betaxolol, ciprofloxacin).
Per- and polyfluoroalkyl substances (PFAS) including PFOS isomers.

Chromatography and ionization:

UPLC: ACQUITY UPLC BEH C18 column (100 mm × 2.1 mm, 1.8 μm), 35 °C, 0.3 mL/min, 10 μL injection.
Mobile phases: A = 95% H2O/5% MeOH with 2 mM ammonium acetate; B = MeOH with 2 mM ammonium acetate. Gradient durations: 22 min for PFOS isomers, 5 min for standards.
Electrospray ionization performed in positive and negative modes; typical capillary voltages 0.3–0.5 kV; source temp ~100 °C; desolvation temp 550 °C and gas flow ~1000 L/hr.

Mass spectrometry and acquisition:

Travelling-wave cyclic ion mobility–MS platform (SELECT SERIES Cyclic IMS) configured to obtain extended ion mobility separations including product ion mobility measurements.
Acquisition strategies included HDMSE (ion-mobility-enabled data-independent acquisition) and HDMS (IM-MS) with and without quadrupole isolation.

Data processing and in-silico annotation:

Data acquisition and review: MassLynx and DriftScope.
Peak detection and initial processing: ApexRT (peak detection), CompareCSV (multicolumn matching with tolerances).
In-silico fragmentation and spectrum prediction: CFM-ID v2.4.
Custom lightweight tools for visualization, CCS calculation and review built with Python libraries (Streamlit, plotly, pandas, numpy, matplotlib).
Workflow steps: multidimensional peak detection/centroiding, CCS calibration, matching experimental precursor and fragment m/z and CCS to in-silico predictions, and generation of CCS-annotated identifications.

Used instrumentation

SELECT SERIES Cyclic IMS (travelling-wave cyclic ion mobility platform).
ACQUITY UPLC system with BEH C18 column (100 × 2.1 mm, 1.8 μm).
MassLynx and DriftScope software for acquisition and drift analysis.
Auxiliary software tools: ApexRT, CompareCSV, CFM-ID v2.4; Python stack (Streamlit, plotly, pandas, numpy, matplotlib) for visualization and CCS calculations.

Main results and discussion

Key findings:

Precursor and product-ion CCS values provided diagnostic information that discriminated linear versus branched PFOS isomers; separation of m/z 379 product ions showed distinct drift-time profiles for linear PFOS and a branched isomer (P5MPHpS).
Drift time and measured CCS differentiated isomeric flavonoid precursors and their product ions (e.g., orientin/isoorientin and vitexin/isovitexin), enabling structural assignment not possible by MS/MS alone.
Small-molecule product ions produced reproducible and specific CCS fingerprints; combining experimentally measured CCS for products with in-silico fragmentation predictions improved annotation confidence for pharmaceutical-relevant compounds.
Workflow examples demonstrated sequential processing steps: peak detection, CCS calibration, centroiding, matching experimental features to predicted fragment m/z and CCS, and annotation of precursor/product pairs. A summary table of precursor and product m/z and CCS values was generated for environmental, natural product and pharmaceutical compounds.
Lightweight application development accelerated data review and allowed rapid interrogation of multidimensional results (m/z, retention time, CCS, intensity).

Benefits and practical applications

Practical advantages demonstrated:

Enhanced isomer resolution for environmental monitoring (PFAS) and natural products, improving identification where m/z and MS/MS are ambiguous.
Product-ion CCS measurements add a new identification parameter for spectral libraries and retrospective data mining.
Combined CCS + in-silico fragmentation increases specificity for metabolite and impurity ID in pharmaceutical and toxicology studies.
Workflow and software integration show feasibility for routine implementation in labs seeking multidimensional confirmation (RT, m/z, CCS, fragmentation).

Future trends and potential uses

Projected developments and opportunities:

Expansion of CCS libraries to include product-ion CCS values alongside precursor CCS to support broader library searching and automated annotation.
Deeper integration of in-silico fragmentation tools and machine-learning models to predict CCS and fragment likelihood, enabling higher-throughput annotation.
Standardization of CCS measurement protocols to improve inter-laboratory comparability and facilitate regulatory acceptance.
Application to complex omics workflows (metabolomics, lipidomics), forensic and environmental screening where isomer differentiation is critical.
Optimization of acquisition strategies (DIA coupled to IM) and faster automated workflows for routine screening and QA/QC use cases.

Conclusion

The travelling-wave cyclic ion mobility–mass spectrometry approach enables high-resolution ion mobility separations and robust CCS measurement for both precursor and product ions. When combined with chromatographic separation, high-resolution MS, in-silico fragmentation and lightweight data-review tools, this multidimensional strategy substantially improves discrimination and annotation of isomeric small molecules across environmental, natural product and pharmaceutical applications. The added dimension of product-ion CCS fingerprints offers a practical pathway to more confident identifications and richer spectral libraries.

Reference

Giles, K., et al. A Cyclic Ion Mobility–Mass Spectrometry System. Analytical Chemistry. 2019;91(13):8564–8573.
Techniques for sample analysis using product ion collision-cross section information. US Patent US12332210B2.
Allen, F., et al. CFM-ID: a web server for annotation, spectrum prediction and metabolite identification from tandem mass spectra. Nucleic Acids Research. 2014;42(Web Server Issue):W94–W99.

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