环境持久性自由基的环境化学行为

阮秀秀; 杜巍萌; 郭凡可; 汤育圆; 钱光人

doi:10.7524/j.issn.0254-6108.2017123002

环境持久性自由基的环境化学行为

1.
上海大学环境与化学工程学院, 上海, 200444
基金项目:
国家自然科学基金（20907029，21577085），上海市自然科学基金（14ZR1415600），上海市教委创新基金（10YZ07）和上海市重点学科建设项目（S30109）资助.

Environmental and chemical behaviors of environmental persistent free radicals

1.
School of Environmental and Chemical Engineering, Shanghai University, Shanghai, 200444, China
Fund Project: Supported by the the National Natural Science Foundation of China(20907029, 21577085),the National Natural Science Foundation of shanghai(14ZR1415600),Shanghai Municipal Commission of Education Innovation Fund-funded projects(10YZ07) and Shanghai Key Disciplines Funded Projects(S30109).

摘要: 环境持久性自由基（Environmental Persistent Free Radicals，EPFRs）是一种新型的环境风险物质，具有较高的反应活性和环境风险性，因其能在环境中持久存在且具有潜在的环境毒理效应而被广泛关注.本文概述了EPFRs的危害、种类、生成机理、影响EPFRs形成的各种因素，并介绍了EPFRs潜在的迁移转化；展望了未来的研究方向.
- 环境持久性自由基 /
- 机理 /
- 危害 /
- 影响因素 /
- 迁移转化
Abstract: Environmental Persistent Free Radicals (EPFRs) are a new category of environmental risk products, which have high reactivity and environmental risk. They have been widely concerned due to their persistence in the environment and potential environment toxicological effects. This paper summarizes the toxicity, types, formation mechanism and influence factors of EPFRs and introduces the potential migration and transformation behavior after EPFRs are released to the environment. The perspectives of EPFRs research in the future are also promoted.
- environmental persistent free radicals(EPFRs) /
- mechanism /
- environmental risks /
- influence factor /
- migration and transformation

[1]	DELLINGER B, LOMNICKI S, KHACHATRYAN L, et al. Formation and stabilization of persistent free radicals[J]. Proceedings of the Combustion Institute International Symposium on Combustion, 2007, 31(1):521-528.
[2]	LOMNICKI S,TRUONG H,VEJERANO E,et al.Copper oxide-based model of persistent free radical formation on combustion -derived particulate matter.[J].Environmental Science & Technology,2008,42(13):4982-4988.
[3]	LYONS M J, SPENCE J B. Environmental free radicals[J]. British Journal of Cancer, 1960, 14(4):703-708.
[4]	HERRING P,KHACHATRYAN L,LOMNICKI S,et al.Paramagnetic centers in particulate formed from the oxidative pyrolysis of 1-methylnaphthalene in the presence of Fe(Ⅲ)₂O₃ nanoparticles[J]. Combustion & Flame, 2013, 160(12):2996-3003.
[5]	GEHLINGW,DELLINGERB.Environmentally persistent free radicals and their lifetimes in PM_2.5.[J]. Environmental Science & Technology, 2013, 47(15):8172-8178.
[6]	SHI T, SCHINS R P, KNAAPEN A M, et al. Hydroxyl radical generation by electron paramagnetic resonance as a new method to monitor ambient particulate matter composition[J]. J Environ Monit, 2003, 5(4):550-556.
[7]	GEHLING W, KHACHATRYAN L, DELLINGER B. Hydroxyl radical generation from environmentally persistent free radicals (EPFRs) in PM_2.5[J]. Environmental Science & Technology, 2014, 48(8):4266-4272.
[8]	ARANGIO A M, TONG H, SOCORRO J, et al. Quantification of environmentally persistent free radicals and reactive oxygen species in atmospheric aerosol particles[J]. Atmospheric Chemistry & Physics, 2016, 16(20):1-24.
[9]	FELDCOOK E, BOVENKAMPLANGLOIS GL, LOMNICKI SM. The effect of particulate matter mineral composition on environmentally persistent free radical (EPFR) formation.[J]. Environmental Science & Technology, 2017, 51(18):10396-10402.
[10]	KIRURI L W, DELLINGER B, LOMNICKI S. Tar balls from deep water horizon oil spill:environmentally persistent free radicals(EPFR) formation during crude weathering[J].Environmental Science & Technology, 2013, 47(9):4220-4226.
[11]	PETRAKIS L, GRANDY D W. Free radicals in coals and synthetic fuels[M]. New York:Elseivier Science Publishers Co.inc, 1983.
[12]	YANG J, PAN B, LI H, et al. Degradation of p-Nitrophenol on biochars:role of persistent free radicals.[J]. Environmental Science & Technology, 2016, 50(2):694-700.
[13]	LIAO S, PAN B, LI H, et al. Detecting free radicals in biochars and determining their ability to inhibit the germination and growth of corn, wheat and rice seedlings[J]. Environmental Science & Technology, 2014, 48(15):8581-8587.
[14]	FANG G, GAO J, LIU C, et al. Key role of persistent free radicals in hydrogen peroxide activation by biochar:implications to organic contaminant degradation[J]. Environmental Science & Technology, 2014, 48(3):1902-1910.
[15]	FANG G, LIU C, GAO J, et al. Manipulation of persistent free radicals in biochar to activate persulfate for contaminant degradation[J]. Environmental Science & Technology, 2015, 49(9):5645-5653.
[16]	FANG G, ZHU C, DIONYSIOU D D, et al. Mechanism of hydroxyl radical generation from biochar suspensions:Implications to diethyl phthalate degradation.[J]. Bioresource Technology, 2015, 176(176):210-217.
[17]
[18]	VALAVANIDIS A, ILIOPOULOS N, GOTSIS G, et al. Persistent free radicals, heavy metals and PAHs generated in particulate soot emissions and residue ash from controlled combustion of common types of plastic[J]. Journal of Hazardous Materials, 2008, 156(1-3):277-284.
[19]	CRUZ A L N D, COOK R L, LOMNICKI S M, et al. Effect of low temperature thermal treatment on soils contaminated with pentachlorophenol and environmentally persistent free radicals[J]. Environmental Science & Technology, 2012, 46(11):5971-5978.
[20]	JIA H, ZHAO S,NULAJI G,et al.Environmentally persistent free radicals in soils of past coking sites:distribution and stabilization.[J]. Environmentalence & Technology, 2017, 51(11):6000-6008.
[21]	JIA H, NULAJI G, GAO H, et al. Formation and stabilization of environmentally persistent free radicals induced by the interaction of anthracene with Fe(Ⅲ)-modified clays[J]. Environmental Science & Technology, 2016, 50(12):6310-6319.
[22]	DELA CRUZ A L, COOK R L, DELLINGER B, et al. Assessment of environmentally persistent free radicals in soils and sediments from three superfund sites.[J]. Environmental Science Processes & Impacts, 2014, 16(1):44-52.
[23]	ESAKA Y, OKUMURA N, UNO B, et al. Electrophoretic analysis of quinone anion radicals in acetonitrile solutions using an on-line radical generator.[J]. Electrophoresis, 2003, 24(10):1635-1640.
[24]	JUNG H, GUO B, KENNEDY A I M. Quantitative measurements of the generation of hydroxyl radicals by soot particles in a surrogate lung fluid[J]. Atmospheric Environment, 2006, 40(6):1043-1052.
[25]	STERNICZUK M, SADO J, STRZELCZAK G, et al. ESR and DFT study of the paramagnetic carbon centers stabilized in γ-irradiated zeolites exposed to carbon monoxide[J]. Microporous & Mesoporous Materials, 2014, 195(1):112-123.
[26]	HALES B J, CASE E E. Immobilized radicals. IV. Biological semiquinone anions and neutral semiquinones[J]. BBA-Bioenergetics, 1981, 637(2):291-302.
[27]	DI V C, NEYMAN K M, RISSE T, et al. Density-functional model cluster studies of EPR g tensors of Fs+ centers on the surface of MgO[J]. Journal of Chemical Physics, 2006, 124(4):1-7.
[28]	JIANG J, BAUER I, PAUL A, et al. Arsenic redox changes by microbially and chemically formed semiquinone radicals and hydroquinones in a humic substance model quinone[J]. Environmental Science & Technology, 2009, 43(10):3639-3645.
[29]	JIAN LONG WANG, LE JIN XU. Advanced oxidation processes for wastewater treatment:formation of hydroxyl radical and application[J]. Critical Reviews in Environmental Science & Technology, 2012, 42(3):251-325.
[30]	KELLEY M A, HEBERT V Y, THIBEAUX T M, et al. Model combustion-generated particulate matter containing persistent free radicals redox cycle to produce reactive oxygen species[J]. Chemical Research in Toxicology, 2013, 26(12):1862-1871.
[31]	QIN J, CHENG Y, SUN M, et al. Catalytic degradation of the soil fumigant 1,3-dichloropropene in aqueous biochar slurry[J]. Science of the Total Environment, 2016, 569(1):1-8.
[32]	QIN Y, ZHANG L, AN T. Hydrothermal carbon mediated Fenton-like reaction mechanism in degradation of alachlor:direct electron transfer from hydrothermal carbon to Fe(Ⅲ)[J]. Acs Applied Materials & Interfaces, 2017, 9(20):17116-17125.
[33]	MASKOS Z, KHACHATRYAN L, DELLINGER B. Role of the filters in the formation and stabilization of semiquinone radicals collected from cigarette smoke.[J]. Energy Fuels, 2013, 27(9):5506-5512.
[34]	FANG G, GAO J, DIONYSIOU D D, et al. Activation of persulfate by quinones:free radical reactions and implication for the degradation of PCBs.[J]. Environmental Science & Technology, 2013, 47(9):4605-4611.
[35]	CHEN N, HUANG Y, HOU X, et al. Photochemistry of hydrochar:reactive oxygen species generation and sulfadimidine degradation[J]. Environmental Science & Technology, 2017,51(19):11278-11287.
[36]	ANDREOZZI L, CASTELVETRO V, CIARDELLI G, et al. Free radical generation upon plasma treatment of cotton fibers and their initiation efficiency in surface-graft polymerization.[J]. Journal of Colloid & Interface Science, 2005, 289(2):455-465.
[37]	PATTERSON M C, DITUSA M F, MCFERRIN C A, et al. Formation of environmentally persistent free radicals (EPFRs) on ZnO at room temperature:Implications for the fundamental model of EPFR generation[J]. Chemical Physics Letters, 2017, 670(1):5-10.
[38]	BäHRLE C, CUSTODIS V, JESCHKE G, et al. In situ observation of radicals and molecular products during lignin pyrolysis.[J]. Chemsuschem, 2014, 7(7):2022-2029.
[39]	LU Y, WEI XY, ZHAO W,et al Structural investigation and application of lignins[J]. Progress in Chemistry, 2013, 25(25):838-858.
[40]	LI F, PAN B, ZHANG D, et al. Organic matter source and degradation as revealed by molecular biomarkers in agricultural soils of Yuanyang terrace[J]. Scientific Reports, 2015, 5(1):1-9.
[41]	ADOUNKPE J, KHACHATRYAN L, DELLINGER B, et al. Radicals from the atmospheric pressure pyrolysis and oxidative pyrolysis of hydroquinone, catechol, and phenol[J]. Energy Fuels, 2009, 23(3):1551-1554.
[42]	王婷, 李浩, 郭惠莹,等. 邻苯二酚-Fe₂O₃和邻苯二酚-CuO体系中持久性自由基的形成机制及特征[J]. 环境化学, 2016, 35(3):423-429. WANG T, HAO L I, GUO H, et al. The formation and characteristics of persistent free radicals in catechol-Fe₂O₃/silica and catechol-CuO/silica systems[J]. Environmental Chemistry, 2016,35(3):423-429(in Chinese).
[43]	韩林, 陈宝梁. 环境持久性自由基的产生机理及环境化学行为[J].化学进展, 2017,29(9):1008-1020. HAN L, CHEN B. Generation mechanism and fate behaviors of environmental persistent free radicals[J]. Progress in Chemistry, 2017,29(9):1008-1020(in Chinese).
[44]	VEJERANO E, LOMNICKI S M, DELLINGER B. Formation and stabilization of combustion-generated, environmentally persistent radicals on Ni(Ⅱ)O supported on a silica surface[J]. Environmental Science & Technology, 2012, 46(17):9406-9411.
[45]	杨颖, 孙振亚. 一类新的环境有害物质——环境持久性自由基(EPFRs)的研究进展[J]. 矿物岩石地球化学通报, 2012, 31(3):287-290. YING Y, ZHENGYA S. The research progress on a new type harmful matter-environmental persistent free radicals(EPFRs)[J]. Bulletin of Mineralogy Petrology & Geochemistry, 2012, 31(3):287-290(in Chinese).
[46]	MASKOS Z, KHACHATRYAN L, DELLINGER B. Formation of the persistent primary radicals from the pyrolysis of tobacco[J]. Energy & Fuels, 2008, 22(2):1027-1033.
[47]	卢超, 郑祥民, 周立旻,等. 城市大气颗粒物表面半醌自由基的测定及特征分析[J]. 环境化学, 2013,32(1):1-6. LU CHAO, ZHENG XIANMIN, ZHOU LIMIN,et al. Measurements and characteristics of semiquinone radicals in urban atmospheric particles[J]. Environmental Chemistry, 2013,32(1):1-6(in Chinese).
[48]	VEJERANO E, LOMNICKI S, DELLINGER B. Formation and stabilization of combustion-generated environmentally persistent free radicals on an Fe(Ⅲ)₂O₃/silica surface[J]. Environmental Science & Technology, 2011, 45(2):589-594.
[49]	QIN J, CHEN Q C, SUN M X, et al. Pyrolysis temperature-induced changes in the catalytic characteristics of rice husk-derived biochar during 1,3-dichloropropene degradation.[J]. Chemical Engineering Journal, 2017, 330(1):804-812
[50]	VEJERANO E, LOMNICKI S, DELLINGER B. Lifetime of combustion-generated environmentally persistent free radicals on Zn(Ⅱ)O and other transition metal oxides.[J]. Journal of Environmental Monitoring Jem, 2012, 14(10):2803-2806.
[51]	YANG L L,LIU G,ZHENGM,et al.Pivotal roles of metal oxides in the formation of environmentally persistent free radicals[J]. Environmental Science & Technology, 2017,51(21):.12329-12336.
[52]	KIRURI L W, KHACHATRYAN L, DELLINGER B, et al. Effec tof copper oxide concentration on the formation and persistency of environmentally persistent free radicals (EPFRs)in particulates[J]. Environmental Science & Technology, 2014, 48(4):2212-2217.
[53]	TRUONG H, LOMNICKI S, DELLINGER B. Potential for misidentification of environmentally persistent free radicals as molecular pollutants in particulate matter[J]. Environmental Science & Technology, 2010, 44(6):1933-1939.
[54]	RASMUSSEN P E, WHEELER A J, HASSAN N M, et al. Monitoring personal, indoor, and outdoor exposures to metals in airborne particulate matter:Risk of contamination during sampling, handling and analysis[J]. Atmospheric Environment, 2007, 41(28):5897-5907.
[55]	PRYOR W A. Oxy-radicals and related species:their formation, lifetimes, and reactions[J]. Annual Review of Physiology, 1986, 48(1):657-667.
[56]	E FINKELSTEIN, G M ROSEN, E J RAUCKMAN. Production of hydroxyl radical by decomposition of superoxide spin-trapped adducts.[J]. Molecular Pharmacology, 1982, 21(2):262-265.
[57]	DELLINGER B, PRYOR W A, CUETO B, et al. The role of combustion-generated radicals in the toxicity of PM 2.5[J]. Proceedings of the Combustion Institute, 2000, 28(2):2675-2681.
[58]	SHINYASHIKI M,KUMAGAI Y,ARIMOTO T,et al. Generation of reactive oxygen species during interaction of diesel exhaust particle components with NADPH-cytochrome P450 reductase and involvement of the bioactivation in the DNA damage.[J]. Free Radical Biology & Medicine, 1997, 22(3):479-487.
[59]	BALAKRISHNA S, LOMNICKI S, MCAVEY K M, et al. Environmentally persistent free radicals amplify ultrafine particle mediated cellular oxidative stress and cytotoxicity[J]. Particle & Fibre Toxicology, 2009, 6(1):11-24.
[60]	DUGAS T R, HEBERT V Y, DELLINGER B, et al. Environmentally persistent free radicals are redox active and more cytotoxic than the average ultrafine particle[C]. Free Radical Biology & Medicine, 2009, 47(1):S121-S121.
[61]	FAHMY B, DING L, YOU D, et al. In vitro and in vivo assessment of pulmonary risk associated with exposure to combustion generated fine particles.[J]. Environmental Toxicology & Pharmacology, 2010, 29(2):173-182.
[62]	PéREZBONILLA M, SALIDO S, VAN BEEK T A, et al. Isolation of antioxidative secoiridoids from olive wood (Olea europaea L.) guided by on-line HPLC-DAD-radical scavenging detection[J]. Food Chemistry, 2011, 124(1):36-41.
[63]	CHUANG G C, XIA H, MAHNE S E, et al. Environmentally persistent free radicals cause apoptosis in HL-1 cardiomyocytes[J]. Cardiovascular Toxicology, 2016,17(2):140-149.
[64]	LEE G I, SARAVIA J, YOU D, et al. Exposure to combustion generated environmentally persistent free radicals enhances severity of influenza virus infection[J]. Particle & Fibre Toxicology, 2014, 11(1):57-66.
[65]	LOMNICKI S, GULLETT B, STöGER T, et al. Combustion by-products and their health effects——combustion engineering and global health in the 21st century:issues and challenges[J]. International Journal of Toxicology, 2014, 33(1):3-13.
[66]	REED J R, CAWLEY G F, ARDOIN T G, et al. Environmentally persistent free radicals inhibit cytochrome P450 activity in rat liver microsomes[J]. Toxicology & Applied Pharmacology, 2014, 277(2):200-209.
[67]	VALKO M, JOMOVA K, RHODES C J, et al. Redox-and non-redox-metal-induced formation of free radicals and their role in human disease.[J]. Archives of Toxicology, 2016, 90(1):1-37.
[68]	SARAVIA J, LEE G I, LOMNICKI S, et al. Particulate matter containing environmentally persistent free radicals and adverse infant respiratory health effects:a review[J]. Journal of Biochemical & Molecular Toxicology, 2013, 27(1):56-68.
[69]	Pérezbonilla M, Salido S, van Beek T A, et al. Radical-scavenging compounds from olive tree (Olea europaea L.) wood.[J]. Journal of Agricultural & Food Chemistry, 2014, 62(1):144-151.
[70]	Mahne S, Chuang G C, Pankey E, et al. Environmentally persistent free radicals decrease cardiac function and increase pulmonary artery pressure.[J]. American Journal of Physiology-Heart and Circulatory Physiology, 2012, 303(9):H1135-H1142.
[71]	Li H, Guo H, Pan B, et al. Catechol degradation on hematite/silica-gas interface as affected by gas composition and the formation of environmentally persistent free radicals[J]. Scientific Reports, 2016, 6(1):1-9.
[72]	DELLINGER B, SQUADRITO GL, CUETO R,et al. Quinoid redox cycling as a mechanism for sustained free radical generation by inhaled airborne particulate matter.[J]. Free Radical Biology & Medicine, 2001, 31(9):1132-1138.
[73]	KHACHATRYAN L, DELLINGER B. Environmentally persistent free radicals (EPFRs)-2. are free hydroxyl radicals generated in aqueous solutions?[J]. Environmental Science & Technology, 2011, 45(21):9232-9239.
[74]	王朋, 吴敏, 李浩,等. 环境持久性自由基对有机污染物环境行为的影响研究进展[J]. 化工进展, 2017, 36(11):4243-4249. WANG P, MIN W U, HAO L I, et al. Formation of environmental persistent free radicals and its influence on organic pollutant behavior:a review[J]. Chemical Industry & Engineering Progress, 2017,36(11):4243-4249(in Chinese).
[75]	KHACHATRYAN L, VEJERANO E, LOMNICKI S, et al. Environmentally persistent free radicals (EPFRs). 1. generation of reactive oxygen species in aqueous solutions.[J]. Environmental Science & Technology, 2011, 45(19):8559-8566.
[76]	CRUZ A L N D, GEHLING W, LOMNICKI S, et al. Detection of environmentally persistent free radicals at a superfund wood treating site.[J]. Environmental Science & Technology, 2011, 45(15):6356-6365.

点击查看大图

计量

文章访问数: 5033
HTML全文浏览数: 4920
PDF下载数: 434
施引文献: 0

环境持久性自由基的环境化学行为

Environmental and chemical behaviors of environmental persistent free radicals

计量

环境持久性自由基的环境化学行为

English Abstract

Environmental and chemical behaviors of environmental persistent free radicals

全文HTML

目录

环境持久性自由基的环境化学行为

Environmental and chemical behaviors of environmental persistent free radicals

计量

出版历程

环境持久性自由基的环境化学行为

English Abstract

Environmental and chemical behaviors of environmental persistent free radicals

全文HTML

目录