Seth R. Newton*, John A. Bowden, Nathaniel Charest, Stephen R. Jackson, Jeremy P. Koelmel, Hannah K. Liberatore, Ashley M. Lin, Charles N. Lowe, Sofia Nieto, Krystal J. Godri Pollitt, Anna R. Robuck, Pawel Rostkowski, Timothy G. Townsend, M. Ariel Geer Wallace and Antony John Williams,
{"title":"填补PFAS检测的空白:将GC-MS非目标分析集成到综合环境监测和暴露评估中","authors":"Seth R. Newton*, John A. Bowden, Nathaniel Charest, Stephen R. Jackson, Jeremy P. Koelmel, Hannah K. Liberatore, Ashley M. Lin, Charles N. Lowe, Sofia Nieto, Krystal J. Godri Pollitt, Anna R. Robuck, Pawel Rostkowski, Timothy G. Townsend, M. Ariel Geer Wallace and Antony John Williams, ","doi":"10.1021/acs.estlett.4c0093010.1021/acs.estlett.4c00930","DOIUrl":null,"url":null,"abstract":"<p >Per- and polyfluoroalkyl substances (PFAS) have garnered increasing attention in recent years, and non-targeted analysis (NTA) has become essential for elucidating novel PFAS structures. NTA and PFAS research have been dominated by liquid chromatography–mass spectrometry (LC-MS) with gas chromatography–mass spectrometry (GC-MS) used less often as evidenced by bibliometrics. However, the performance of GC-MS in NTA studies (GC-NTA) rivals that of LC-ESI-MS, and GC-MS is shown to cover a complementary chemical space. An LC-ESI-MS amenability model applied to a list of approximately 12,000 PFAS revealed that less than 10% of known PFAS chemistry is predicted to be amenable to typical LC-MS analysis. Therefore, there is strong potential for applying GC-MS methods to more fully assess the PFAS environmental contamination landscape, uniquely shedding light on both known and novel PFAS, especially within the chemical space realm of volatile and semivolatile PFAS. Waste streams from fluorochemical manufacturing facilities have been heavily studied using LC-MS and targeted GC-MS; however, GC-NTA is needed to discover novel PFAS that are not amenable to LC-MS emitted from facilities. Studies on the incineration of PFAS-containing materials, such as aqueous film forming foam, have focused on the destruction of parent compounds, and little is known about the transformation products formed during such processes. GC-NTA holds the potential to elucidate transformation products formed when PFAS are incinerated. Wastewater treatment plants and landfills are known sources of PFAS to the environment, yet GC-NTA is needed to understand air emissions of PFAS and PFAS transformation products from these sources. Consumer products are known to lead to indoor exposures to PFAS via emissions to air and dust, but research in this area has either used LC-MS or targeted GC-MS. Despite the challenges with advancing GC-NTA, we call on NTA researchers, grantors, managers, and other stakeholders to recognize the potential and necessity of GC-NTA in PFAS research so that we may face these challenges together.</p>","PeriodicalId":37,"journal":{"name":"Environmental Science & Technology Letters Environ.","volume":"12 2","pages":"104–112 104–112"},"PeriodicalIF":8.9000,"publicationDate":"2025-01-23","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Filling the Gaps in PFAS Detection: Integrating GC-MS Non-Targeted Analysis for Comprehensive Environmental Monitoring and Exposure Assessment\",\"authors\":\"Seth R. Newton*, John A. Bowden, Nathaniel Charest, Stephen R. Jackson, Jeremy P. Koelmel, Hannah K. Liberatore, Ashley M. Lin, Charles N. Lowe, Sofia Nieto, Krystal J. Godri Pollitt, Anna R. Robuck, Pawel Rostkowski, Timothy G. Townsend, M. Ariel Geer Wallace and Antony John Williams, \",\"doi\":\"10.1021/acs.estlett.4c0093010.1021/acs.estlett.4c00930\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p >Per- and polyfluoroalkyl substances (PFAS) have garnered increasing attention in recent years, and non-targeted analysis (NTA) has become essential for elucidating novel PFAS structures. NTA and PFAS research have been dominated by liquid chromatography–mass spectrometry (LC-MS) with gas chromatography–mass spectrometry (GC-MS) used less often as evidenced by bibliometrics. However, the performance of GC-MS in NTA studies (GC-NTA) rivals that of LC-ESI-MS, and GC-MS is shown to cover a complementary chemical space. An LC-ESI-MS amenability model applied to a list of approximately 12,000 PFAS revealed that less than 10% of known PFAS chemistry is predicted to be amenable to typical LC-MS analysis. 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Wastewater treatment plants and landfills are known sources of PFAS to the environment, yet GC-NTA is needed to understand air emissions of PFAS and PFAS transformation products from these sources. Consumer products are known to lead to indoor exposures to PFAS via emissions to air and dust, but research in this area has either used LC-MS or targeted GC-MS. 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Filling the Gaps in PFAS Detection: Integrating GC-MS Non-Targeted Analysis for Comprehensive Environmental Monitoring and Exposure Assessment
Per- and polyfluoroalkyl substances (PFAS) have garnered increasing attention in recent years, and non-targeted analysis (NTA) has become essential for elucidating novel PFAS structures. NTA and PFAS research have been dominated by liquid chromatography–mass spectrometry (LC-MS) with gas chromatography–mass spectrometry (GC-MS) used less often as evidenced by bibliometrics. However, the performance of GC-MS in NTA studies (GC-NTA) rivals that of LC-ESI-MS, and GC-MS is shown to cover a complementary chemical space. An LC-ESI-MS amenability model applied to a list of approximately 12,000 PFAS revealed that less than 10% of known PFAS chemistry is predicted to be amenable to typical LC-MS analysis. Therefore, there is strong potential for applying GC-MS methods to more fully assess the PFAS environmental contamination landscape, uniquely shedding light on both known and novel PFAS, especially within the chemical space realm of volatile and semivolatile PFAS. Waste streams from fluorochemical manufacturing facilities have been heavily studied using LC-MS and targeted GC-MS; however, GC-NTA is needed to discover novel PFAS that are not amenable to LC-MS emitted from facilities. Studies on the incineration of PFAS-containing materials, such as aqueous film forming foam, have focused on the destruction of parent compounds, and little is known about the transformation products formed during such processes. GC-NTA holds the potential to elucidate transformation products formed when PFAS are incinerated. Wastewater treatment plants and landfills are known sources of PFAS to the environment, yet GC-NTA is needed to understand air emissions of PFAS and PFAS transformation products from these sources. Consumer products are known to lead to indoor exposures to PFAS via emissions to air and dust, but research in this area has either used LC-MS or targeted GC-MS. Despite the challenges with advancing GC-NTA, we call on NTA researchers, grantors, managers, and other stakeholders to recognize the potential and necessity of GC-NTA in PFAS research so that we may face these challenges together.
期刊介绍:
Environmental Science & Technology Letters serves as an international forum for brief communications on experimental or theoretical results of exceptional timeliness in all aspects of environmental science, both pure and applied. Published as soon as accepted, these communications are summarized in monthly issues. Additionally, the journal features short reviews on emerging topics in environmental science and technology.
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