Certain poly-and perfluoroalkyl substances(PFASs)exhibit significant bioaccumulation/biomagnification behaviors in ecosystems.PFASs,such as perfluorooctane sulfonate(PFOS),perfluorooctanoic acid(PFOA),perfluorohexanes...Certain poly-and perfluoroalkyl substances(PFASs)exhibit significant bioaccumulation/biomagnification behaviors in ecosystems.PFASs,such as perfluorooctane sulfonate(PFOS),perfluorooctanoic acid(PFOA),perfluorohexanesulfonic acid(PFHxS)and related precursors,have elicited attention from both public and national regulatory agencies,which has resulted in worldwide restrictions on their production and use.Apex predators occupy the top trophic positions in ecosystems and are most affected by the biomagnification behavior of PFASs.Meanwhile,the long lifespans of apex predators also lead to the high body burden of PFASs.The high body burden of PFASs might be linked to adverse health effects and even pose a potential threat to their reproduction.As seen in previous reviews of PFASs,knowledge is lacking between the current stage of the PFAS body burden and related effects in apex predators.This review summarized PFAS occurrence in global apex predators,including information on the geographic distribution,levels,profiles,and tissue distribution,and discussed the trophic transfer and ecotoxicity of PFASs.In the case where legacy PFASs were restricted under international convention,the occurrence of novel PFASs,such as 6:2 chlorinated polyfluorinated ether sulfonate(6:2 Cl-PFESA)and perfluoroethylcyclohexane sulfonate(PFECHS),in apex predators arose as an emerging issue.Future studies should develop an effective analytical method and focus on the toxicity and trophic transfer behavior of novel PFASs.展开更多
Poly-and perfluoroalkyl substances(PFAS),including perfluorooctanoic acid(PFOA)and perfluorooctane sul-fonate(PFOS),are persistent environmental pollutants with potential toxicological effects on human health.The aim ...Poly-and perfluoroalkyl substances(PFAS),including perfluorooctanoic acid(PFOA)and perfluorooctane sul-fonate(PFOS),are persistent environmental pollutants with potential toxicological effects on human health.The aim of this study was to investigate the impact of PFOS and PFOA on the effectiveness of selected drugs used in the treatment of prostate cancer based on in vitro tests on cell lines.Three cell lines were used in the study:two human prostate cancer cells(DU-145 and PC3)and one human normal prostate cell line(PNT1A).Using dose-response experiments,it was observed that PFAS had differential effects on cancer and normal cells.At low concentrations,PFOA and PFOS stimulated the proliferation of cancer cells,particularly PC3,while higher concentrations led to reduced viability.In normal cells,PFOS exhibited greater cytotoxicity compared to PFOA.Furthermore,PFOS enhanced docetaxel cytotoxicity in PC3 cells but reduced its efficacy in DU-145 cells.Similarly,PFOA diminished cabazitaxel effectiveness in DU-145 cells,suggesting PFAS-drug interactions may depend on the cell type,drug,and PFAS concentration.Results suggest that PFAS may influence cellular processes through receptor-mediated pathways,oxidative stress modulation,and protein binding,altering drug bioavailability and cellular uptake.The study also highlights the non-monotonic dose-response relationships observed in PFAS-treated cells.These findings raise concerns about the potential risks associated with PFAS exposure,particularly in the context of cancer treatment.Future studies should focus on long-term,low-dose PFAS exposure,the use of primary cells,and the molecular mechanisms driving these interactions to better inform therapeutic strategies.展开更多
To efficiently remove perfluorooctanoic acid(PFOA),we developed a composite of magnetic Fe_(3)O_(4)nanocrystals and MIL-101(an iron-based metal organic framework).Because of its high surface area,porous structure,and ...To efficiently remove perfluorooctanoic acid(PFOA),we developed a composite of magnetic Fe_(3)O_(4)nanocrystals and MIL-101(an iron-based metal organic framework).Because of its high surface area,porous structure,and complexation between PFOA as confirmed by experimental results and density functional theory simulation,the magnetic composite showed a Langmuir adsorption capacity of 415 mg/g in the presence of various groundwater components,and thus adsorbed PFOA at environment-relevant concentration within 20 min.The catalyst loaded with PFOA can then be magnetically separated from the synthetic groundwater.This adsorption step concentrated PFOA near MIL-101 and resulted in a fast decomposition rate in the decomposition step,where MIL-101 served as an efficient Fenton agent due to its abundant Fe^(3+)/Fe^(2+)sites.Meanwhile,the alternative magnetic field was introduced to change the production pathway of reactive oxygen species and superoxide radical anions were produced,which was critical for PFOA degradation.In addition,the inductive heating effect heat the magnetic particles to445 K through an in-situ approach,which thus further accelerated Fenton reactions rate.In addition,and achieved a complete degradation of PFOA within 30 min.This newly developed Fenton catalyst demonstrates advantages over conventionally heterogeneous and homogeneous catalysts,and thus is promising for practical applications.展开更多
Per-and polyfluoroalkyl substances(PFAS),a class of synthetic fluorine-containing organic compounds,pose a serious threat to the ecological environment and human health due to their persistence,bioaccumulation,and ext...Per-and polyfluoroalkyl substances(PFAS),a class of synthetic fluorine-containing organic compounds,pose a serious threat to the ecological environment and human health due to their persistence,bioaccumulation,and extensive toxicity.Non-targeted screening(NTS)is a key method for identifying and determining unknown PFAS,which is crucial to the understanding of their exposure pathway and health risks.Hence,this review focuses on NTS techniques for PFAS in the environment.Firstly,high-resolution mass spectrometry and ion mobility innovations enabling novel PFAS/isomer identification are evaluated.Afterwards,pretreatment optimization(e.g.,solid-phase extraction and emerging adsorbents)is summarized by analyzing the advantages of each method and the challenges posed by the limited datasets,while also outlining their applicable scenarios.Analytical challenges from structural complexity(short-chain substitutes and ether-based fluorine-modulated polymers)and matrix effects are discussed.Lastly,practical implications for environmental health and the future development potential of NTS technologies for PFAS are presented.Overall,this review proposes a science-based framework for monitoring and regulatory prioritization,with the expectation of supporting PFAS management and mitigation.展开更多
基金supported by the National Natural Science Foundation of China(Nos.22022611,21906096)the National Key Research and Development Program of China(No.2020YFA0907500)the Youth Innovation Promotion Association of CAS(No.2018052).
文摘Certain poly-and perfluoroalkyl substances(PFASs)exhibit significant bioaccumulation/biomagnification behaviors in ecosystems.PFASs,such as perfluorooctane sulfonate(PFOS),perfluorooctanoic acid(PFOA),perfluorohexanesulfonic acid(PFHxS)and related precursors,have elicited attention from both public and national regulatory agencies,which has resulted in worldwide restrictions on their production and use.Apex predators occupy the top trophic positions in ecosystems and are most affected by the biomagnification behavior of PFASs.Meanwhile,the long lifespans of apex predators also lead to the high body burden of PFASs.The high body burden of PFASs might be linked to adverse health effects and even pose a potential threat to their reproduction.As seen in previous reviews of PFASs,knowledge is lacking between the current stage of the PFAS body burden and related effects in apex predators.This review summarized PFAS occurrence in global apex predators,including information on the geographic distribution,levels,profiles,and tissue distribution,and discussed the trophic transfer and ecotoxicity of PFASs.In the case where legacy PFASs were restricted under international convention,the occurrence of novel PFASs,such as 6:2 chlorinated polyfluorinated ether sulfonate(6:2 Cl-PFESA)and perfluoroethylcyclohexane sulfonate(PFECHS),in apex predators arose as an emerging issue.Future studies should develop an effective analytical method and focus on the toxicity and trophic transfer behavior of novel PFASs.
文摘Poly-and perfluoroalkyl substances(PFAS),including perfluorooctanoic acid(PFOA)and perfluorooctane sul-fonate(PFOS),are persistent environmental pollutants with potential toxicological effects on human health.The aim of this study was to investigate the impact of PFOS and PFOA on the effectiveness of selected drugs used in the treatment of prostate cancer based on in vitro tests on cell lines.Three cell lines were used in the study:two human prostate cancer cells(DU-145 and PC3)and one human normal prostate cell line(PNT1A).Using dose-response experiments,it was observed that PFAS had differential effects on cancer and normal cells.At low concentrations,PFOA and PFOS stimulated the proliferation of cancer cells,particularly PC3,while higher concentrations led to reduced viability.In normal cells,PFOS exhibited greater cytotoxicity compared to PFOA.Furthermore,PFOS enhanced docetaxel cytotoxicity in PC3 cells but reduced its efficacy in DU-145 cells.Similarly,PFOA diminished cabazitaxel effectiveness in DU-145 cells,suggesting PFAS-drug interactions may depend on the cell type,drug,and PFAS concentration.Results suggest that PFAS may influence cellular processes through receptor-mediated pathways,oxidative stress modulation,and protein binding,altering drug bioavailability and cellular uptake.The study also highlights the non-monotonic dose-response relationships observed in PFAS-treated cells.These findings raise concerns about the potential risks associated with PFAS exposure,particularly in the context of cancer treatment.Future studies should focus on long-term,low-dose PFAS exposure,the use of primary cells,and the molecular mechanisms driving these interactions to better inform therapeutic strategies.
基金financial support from the National Key Research and Development Program of China(No.2022YFC3205300)National Natural Science Foundation of China(Nos.52100178 and 52370072)。
文摘To efficiently remove perfluorooctanoic acid(PFOA),we developed a composite of magnetic Fe_(3)O_(4)nanocrystals and MIL-101(an iron-based metal organic framework).Because of its high surface area,porous structure,and complexation between PFOA as confirmed by experimental results and density functional theory simulation,the magnetic composite showed a Langmuir adsorption capacity of 415 mg/g in the presence of various groundwater components,and thus adsorbed PFOA at environment-relevant concentration within 20 min.The catalyst loaded with PFOA can then be magnetically separated from the synthetic groundwater.This adsorption step concentrated PFOA near MIL-101 and resulted in a fast decomposition rate in the decomposition step,where MIL-101 served as an efficient Fenton agent due to its abundant Fe^(3+)/Fe^(2+)sites.Meanwhile,the alternative magnetic field was introduced to change the production pathway of reactive oxygen species and superoxide radical anions were produced,which was critical for PFOA degradation.In addition,the inductive heating effect heat the magnetic particles to445 K through an in-situ approach,which thus further accelerated Fenton reactions rate.In addition,and achieved a complete degradation of PFOA within 30 min.This newly developed Fenton catalyst demonstrates advantages over conventionally heterogeneous and homogeneous catalysts,and thus is promising for practical applications.
基金supported by the Program for the National Natural Science Foundation of China(52300202)Guizhou University High-level Talent Research and Platform Construction Funds([2024]17).
文摘Per-and polyfluoroalkyl substances(PFAS),a class of synthetic fluorine-containing organic compounds,pose a serious threat to the ecological environment and human health due to their persistence,bioaccumulation,and extensive toxicity.Non-targeted screening(NTS)is a key method for identifying and determining unknown PFAS,which is crucial to the understanding of their exposure pathway and health risks.Hence,this review focuses on NTS techniques for PFAS in the environment.Firstly,high-resolution mass spectrometry and ion mobility innovations enabling novel PFAS/isomer identification are evaluated.Afterwards,pretreatment optimization(e.g.,solid-phase extraction and emerging adsorbents)is summarized by analyzing the advantages of each method and the challenges posed by the limited datasets,while also outlining their applicable scenarios.Analytical challenges from structural complexity(short-chain substitutes and ether-based fluorine-modulated polymers)and matrix effects are discussed.Lastly,practical implications for environmental health and the future development potential of NTS technologies for PFAS are presented.Overall,this review proposes a science-based framework for monitoring and regulatory prioritization,with the expectation of supporting PFAS management and mitigation.
