Enhanced Quantitative Analysis of Polychlorinated Paraffins by Comprehensive GCxGC-HRTOFMS with Negative Chemical Ionization
Applications | 2022 | LECOInstrumentation
Persistent organic pollutants (POPs) such as polychlorinated paraffins (PCPs) accumulate in household dust and pose potential health risks via chronic exposure. Due to their widespread use as flame retardants, plasticizers and lubricants, PCPs are ubiquitous in indoor environments. Their structural complexity and low concentrations in dust require advanced analytical strategies to achieve reliable detection and quantification.
This work presents a robust method combining comprehensive two-dimensional gas chromatography (GC×GC) with high-resolution time-of-flight mass spectrometry (HRTOFMS) operating in electron capture negative ionization (ECNI) mode. The primary goals were to improve sensitivity and selectivity for short-chain (C10–C13) and medium-chain (C14–C17) PCPs in dust samples, minimize isobaric interferences, and demonstrate quantitative performance against a NIST standard reference material (SRM 2585) and real household dust extracts.
Sample preparation involved solvent extraction of dust (dichloromethane/hexane), concentration under nitrogen and spiking with a hexachlorocyclohexane surrogate. Calibration standards spanning 0.10–15.0 µg/mL were prepared using SCCP and MCCP mixtures. GC×GC separations exploited a nonpolar primary column (HP-5MS UI) and a mid-polar secondary column (Rxi-17Sil MS) with a quad-jet modulator. ECNI-HRTOFMS was configured for high mass resolution (R = 25,000 at m/z 219) and accurate mass (<1 ppm) acquisition of [M–Cl] and [M–HCl] ions.
GC×GC achieved clear separation of 12 PCP “clouds” based on constant sum of carbon and chlorine atoms. ECNI-HRTOFMS provided enhanced sensitivity for higher chlorinated homologs and minimized coeluting interferences. Calibration curves for groups 5–8 exhibited excellent linearity (R² > 0.99, quadratic fit). Analysis of NIST SRM 2585 returned SCCP and MCCP levels of 11.1 and 11.2 µg/g, in close agreement with literature (7.6–8.7 and 10.0–16.4 µg/g). A household dust sample yielded 8.1 µg/g SCCP and 8.8 µg/g MCCP.
The method delivers high selectivity and reproducible quantification of complex PCP mixtures in environmental matrices. It can be implemented in routine monitoring laboratories for indoor air quality assessment, regulatory compliance of POPs, and risk evaluation in consumer products.
Advancements in ionization chemistries and data-processing algorithms may further enhance detection limits and congener specificity. Integration with automated sample prep and machine-learning–driven cloud classification could streamline high-throughput screening of emerging chlorinated contaminants.
Comprehensive GC×GC-ECNI-HRTOFMS with cloud-based quantitation provides a powerful platform for accurate, sensitive analysis of short- and medium-chain PCPs in dust. The approach overcomes chromatographic and mass spectral challenges, delivering quantitative results consistent with reference standards and supporting expanded environmental monitoring.
GCxGC, GC/MSD, GC/HRMS, GC/TOF
IndustriesEnvironmental
ManufacturerAgilent Technologies, LECO
Summary
Importance of the Topic
Persistent organic pollutants (POPs) such as polychlorinated paraffins (PCPs) accumulate in household dust and pose potential health risks via chronic exposure. Due to their widespread use as flame retardants, plasticizers and lubricants, PCPs are ubiquitous in indoor environments. Their structural complexity and low concentrations in dust require advanced analytical strategies to achieve reliable detection and quantification.
Objectives and Study Overview
This work presents a robust method combining comprehensive two-dimensional gas chromatography (GC×GC) with high-resolution time-of-flight mass spectrometry (HRTOFMS) operating in electron capture negative ionization (ECNI) mode. The primary goals were to improve sensitivity and selectivity for short-chain (C10–C13) and medium-chain (C14–C17) PCPs in dust samples, minimize isobaric interferences, and demonstrate quantitative performance against a NIST standard reference material (SRM 2585) and real household dust extracts.
Methodology and Instrumentation
Sample preparation involved solvent extraction of dust (dichloromethane/hexane), concentration under nitrogen and spiking with a hexachlorocyclohexane surrogate. Calibration standards spanning 0.10–15.0 µg/mL were prepared using SCCP and MCCP mixtures. GC×GC separations exploited a nonpolar primary column (HP-5MS UI) and a mid-polar secondary column (Rxi-17Sil MS) with a quad-jet modulator. ECNI-HRTOFMS was configured for high mass resolution (R = 25,000 at m/z 219) and accurate mass (<1 ppm) acquisition of [M–Cl] and [M–HCl] ions.
Instrumentation Used
- Agilent 7890B GC with LECO Dual Stage QuadJet™ modulator
- Primary column: HP-5MS UI, 30 m × 0.25 mm × 0.25 µm
- Secondary column: Rxi-17Sil MS, 1.2 m × 0.25 mm × 0.10 µm
- LECO Pegasus HRT+ 4D HRTOFMS with ECNI (CH₄ reagent gas)
- Injection: 3 µL splitless at 280 °C; carrier gas He at 1.0 mL/min
- Oven program: 60 °C ramp to 320 °C; secondary oven/modulator at +15 °C offsets
Main Results and Discussion
GC×GC achieved clear separation of 12 PCP “clouds” based on constant sum of carbon and chlorine atoms. ECNI-HRTOFMS provided enhanced sensitivity for higher chlorinated homologs and minimized coeluting interferences. Calibration curves for groups 5–8 exhibited excellent linearity (R² > 0.99, quadratic fit). Analysis of NIST SRM 2585 returned SCCP and MCCP levels of 11.1 and 11.2 µg/g, in close agreement with literature (7.6–8.7 and 10.0–16.4 µg/g). A household dust sample yielded 8.1 µg/g SCCP and 8.8 µg/g MCCP.
Benefits and Practical Applications
The method delivers high selectivity and reproducible quantification of complex PCP mixtures in environmental matrices. It can be implemented in routine monitoring laboratories for indoor air quality assessment, regulatory compliance of POPs, and risk evaluation in consumer products.
Future Trends and Potential Applications
Advancements in ionization chemistries and data-processing algorithms may further enhance detection limits and congener specificity. Integration with automated sample prep and machine-learning–driven cloud classification could streamline high-throughput screening of emerging chlorinated contaminants.
Conclusion
Comprehensive GC×GC-ECNI-HRTOFMS with cloud-based quantitation provides a powerful platform for accurate, sensitive analysis of short- and medium-chain PCPs in dust. The approach overcomes chromatographic and mass spectral challenges, delivering quantitative results consistent with reference standards and supporting expanded environmental monitoring.
References
- Moschet C., Anumol T., Lew B.M., Bennett D.H., Young T.M., Environ. Sci. Technol. 52(5):2878–2887 (2018)
- Shang H., Fan X., Kubwabo C., Rasmussen P.E., Environ. Sci. Pollut. Res. 26:7453–7462 (2019)
- Brits M., de Boer J., Rohwer E.R., De Vos J., Weiss J.M., Brandsma S.H., Chemosphere 238:124643 (2019)
- Brandsma S.H., Brits M., Groenewoud Q.R., van Velzen M.J.M., Leonards P.E.G., de Boer J., Environ. Sci. Technol. 53(13):7595–7603 (2019)
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