Comprehensive, Non-Target Characterization of Environmental Exposome Samples Using GC×GC and High Resolution Time-of-Flight Mass Spectrometr
Posters | 2019 | LECOInstrumentation
Environmental exposome analysis aims to detect both expected and unexpected chemical constituents in complex matrices. Traditional targeted workflows can overlook novel or emerging contaminants. The integration of comprehensive two-dimensional gas chromatography (GC×GC) with high-resolution time-of-flight mass spectrometry (HR-TOFMS) provides enhanced separation, sensitivity, and spectral fidelity, enabling robust non-targeted investigations in environmental chemistry.
This study, conducted by LECO Corporation in collaboration with the U.S. EPA, assessed the performance of GC×GC-HR-TOFMS for non-target analysis. Ten environmental exposome samples, each spiked with 100–400 known compounds, were analyzed in a blinded phase and then re-evaluated after revealing the target lists. Key goals included measuring spike detection rates, evaluating chromatographic resolution gains, and refining confidence scoring for unknown identification.
Samples were analyzed in both electron ionization (EI) and chemical ionization (CI) modes under 1D and GC×GC conditions. Data acquisition employed high-resolution detection (≥25,000 FWHM) at 200 spectra/sec for GC×GC. LECO’s ChromaTOF software automated deconvolution and applied a tiered confidence scoring (A, B, X) based on spectral match, mass accuracy (±5 ppm), presence of molecular ion, and retention index agreement. Instrumentation details are listed below.
GC×GC separation dramatically improved peak capacity, resolving co-eluting analytes that overlapped in one-dimensional runs. Initial NIST 17 coverage of spiked compounds averaged 81% per sample. In the blinded phase, ~85% of spikes were correctly identified (tiers A and B). After disclosing target lists, overall success increased to ~92%, with tier X capturing compounds reclassified upon list reveal. Enhanced mass accuracy and deconvolution allowed confident discrimination of isomeric and trace constituents.
The development of high-resolution GC-MS spectral libraries tailored for environmental exposome studies will further enhance identification rates. Integration of machine learning for automated feature prioritization and real-time deconvolution could accelerate non-target screening. Expansion to other matrices and coupling with ion mobility spectrometry represent promising avenues for comprehensive exposome characterization.
The combination of GC×GC and HR-TOFMS, supported by advanced deconvolution software, offers a powerful platform for non-targeted environmental analysis. This approach achieves high detection coverage in complex samples, enables reliable identification of unknowns, and lays the groundwork for improved spectral libraries and automated workflows.
James Carlson, Todd Richards, Joe Binkley, Lorne Fell. Comprehensive, Non-Target Characterization of Environmental Exposome Samples Using GC×GC and High Resolution Time-of-Flight Mass Spectrometry. LECO Corporation, Saint Joseph, MI, USA.
GCxGC, GC/MSD, GC/HRMS, GC/TOF
IndustriesEnvironmental
ManufacturerLECO
Summary
Significance of the Topic
Environmental exposome analysis aims to detect both expected and unexpected chemical constituents in complex matrices. Traditional targeted workflows can overlook novel or emerging contaminants. The integration of comprehensive two-dimensional gas chromatography (GC×GC) with high-resolution time-of-flight mass spectrometry (HR-TOFMS) provides enhanced separation, sensitivity, and spectral fidelity, enabling robust non-targeted investigations in environmental chemistry.
Objectives and Study Overview
This study, conducted by LECO Corporation in collaboration with the U.S. EPA, assessed the performance of GC×GC-HR-TOFMS for non-target analysis. Ten environmental exposome samples, each spiked with 100–400 known compounds, were analyzed in a blinded phase and then re-evaluated after revealing the target lists. Key goals included measuring spike detection rates, evaluating chromatographic resolution gains, and refining confidence scoring for unknown identification.
Methodology and Instrumentation
Samples were analyzed in both electron ionization (EI) and chemical ionization (CI) modes under 1D and GC×GC conditions. Data acquisition employed high-resolution detection (≥25,000 FWHM) at 200 spectra/sec for GC×GC. LECO’s ChromaTOF software automated deconvolution and applied a tiered confidence scoring (A, B, X) based on spectral match, mass accuracy (±5 ppm), presence of molecular ion, and retention index agreement. Instrumentation details are listed below.
Instrumentation
- Gas Chromatograph: Agilent 7890B with dual-stage thermal modulator and secondary oven
- Mass Spectrometer: LECO Pegasus GC-HRT+ 4D HR-TOFMS
- Ion Sources: EI at 250 °C; CI (CH₄ + 5% NH₃) at 200 °C
- Columns: Rxi-5MS (30 m × 0.25 mm × 0.25 µm) primary; Rxi-17Sil MS (0.6 m × 0.25 mm × 0.25 µm) secondary
- Modulation Period: 4 s
- Injection: 1 µL (10:1 DCM dilution), split 10:1 (splitless for CI), inlet at 250 °C
- Carrier Gas: Helium at 1.4 mL/min constant flow
Main Results and Discussion
GC×GC separation dramatically improved peak capacity, resolving co-eluting analytes that overlapped in one-dimensional runs. Initial NIST 17 coverage of spiked compounds averaged 81% per sample. In the blinded phase, ~85% of spikes were correctly identified (tiers A and B). After disclosing target lists, overall success increased to ~92%, with tier X capturing compounds reclassified upon list reveal. Enhanced mass accuracy and deconvolution allowed confident discrimination of isomeric and trace constituents.
Benefits and Practical Applications
- Superior chromatographic resolution reduces co-elution and improves deconvolution accuracy.
- High-resolution accurate mass data enables precise molecular formula determination.
- Automated confidence scoring streamlines review of hundreds of potential analytes.
- Combined EI/CI workflows support confirmation of low-abundance or labile compounds.
Future Trends and Potential Applications
The development of high-resolution GC-MS spectral libraries tailored for environmental exposome studies will further enhance identification rates. Integration of machine learning for automated feature prioritization and real-time deconvolution could accelerate non-target screening. Expansion to other matrices and coupling with ion mobility spectrometry represent promising avenues for comprehensive exposome characterization.
Conclusion
The combination of GC×GC and HR-TOFMS, supported by advanced deconvolution software, offers a powerful platform for non-targeted environmental analysis. This approach achieves high detection coverage in complex samples, enables reliable identification of unknowns, and lays the groundwork for improved spectral libraries and automated workflows.
References
James Carlson, Todd Richards, Joe Binkley, Lorne Fell. Comprehensive, Non-Target Characterization of Environmental Exposome Samples Using GC×GC and High Resolution Time-of-Flight Mass Spectrometry. LECO Corporation, Saint Joseph, MI, USA.
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