The Synthesis of Surfactant Coated Glass Foam to Extract and Determine Trace Quantities of Polycyclic Aromatic Hydrocarbons in Drinking Water
Subject Areas : Journal of Chemical Health RisksSamaneh Ahmadi-Asoori 1 , Ali Mirabi 2 , Elham Tazikeh-Lemseki 3 , Esmaeil Babanezhad Orimi 4 , Mohammad Habibi Juybari 5
1 - Department of Chemistry, Gorgan Branch, Islamic Azad University, Gorgan, Iran
2 - Department of Chemistry, Qaemshahr Branch, Islamic Azad University, Qaemshahr, Iran
3 - Department of Chemistry, Gorgan Branch, Islamic Azad University, Gorgan, Iran
4 - Department of Environmental Health, Faculty of Health, Mazandaran University of Medical Sciences, Sari, Iran
5 - Department of Chemistry, Gorgan Branch, Islamic Azad University, Gorgan, Iran
Keywords:
Abstract :
1. Reemtsma T., Weiss S., Mueller J., Petrovic M.,Gonzalez S., Barcelo D., Ventura F. Knepper T.P., 2006. Polar Pollutants Entry into the Water Cycle by Municipal Wastewater: A European Perspective. Environ Sci Technol. 40, 5451−5458.
2. Sonune A., Ghate R., 2004. Developments in wastewater treatment methods. Desalination. 167, 55−63.
3. Sanchez-Avila J., Bonet J., Velasco G., Lacorte S., 2009. Determination and occurrence of phthalates, alkyl phenols, bisphenol A, PBDEs, PCB sand PAHs in an industrial sewage grid discharging to a Municipal Wastewater Treatment Plant. Sci Total Environ. 407, 4157−4167.
4. Behera B.K., Das A., Sarkar D.J., Weerathunge P., Parida P.K., Das B.K., Thavamani P., Ramanathan R., Bansal V., 2018. Polycyclic aromatic hydrocarbons (PAHs) in inland aquatic ecosystems: Perils and remedies through biosensors and bioremediation. Environ Pollut. 241, 212−233.
5. Tsibart A.S., Gennadiev A.N., 2013. Polycyclic aromatic hydrocarbons in soils: Sources, behavior, and indication significance (a review). Eurasian Soil Sci. 46, 728−741.
6. Wilson S.C., Jones K.C., 1993. Bioremediation of soil contaminated with poly nuclear aromatic hydrocarbons (PAHs): A review Environ Pollut. 81, 229−249.
7.Sun C., Zhang J., Ma Q., Chen Y., Ju H., 2017. Polycyclic aromatic hydrocarbons (PAHs) in water and sediment from a river basin: sediment water partitioning, source identification and environmental health risk assessment. Environ Geochem Health. 39, 63−74.
8. Nwaichi E.O., Ntorgbo S.A., 2016. Assessment of PAHs levels in some fish and seafood from different coastal waters in the Niger Delta. Toxicol Rep. 3, 167−172.
9. Shimada T., Fujii-Kuriyama Y., 2004. Metabolic activation of polycyclic aromatic hydrocarbons to carcinogens by cytochromes P450 1A1 and 1B1.Cancer Sci. 95, 1−6.
10. Plant A.L., Knapp R.D., Smith L.C., 1987. Mechanism and rate of permeation of cells by polycyclic aromatic hydrocarbons. J Biol Chem. 262, 2514−2519.
11. Pratt M.M., John K., MacLean A.B., Afework S., Phillips D.H., Poirier M.C., 2011. Polycyclic aromatic hydrocarbon (PAH) exposure and DNA adduct semi-quantitation in archived human tissues. Int J Environ Res Public Health. 8, 2675−2691.
12. Agency for Toxic Substances and Disease Registry, ATSDR. Toxicological profile for polycyclic aromatic hydrocarbons. Atlanta; 1995.
13. Federal Institute for Risk Assessment, BfR. Carcinogenic polycyclic aromatic hydrocarbons (PAHs) in consumer products to be regulated by the EU-risk assessment by BfR in the context of a restriction proposal under REACH, Opinion Nr. 032/2010. Berlin, German. 2010.
14. Ballesteros R., Hernandez J.J., Lyons L.L., 2010. An experimental study of the influence of bio fuel origin on particle-associated. Atmos Environ. 44, 930–8.
15. Song YF., Jing X., Fleischmann S., Wilke B.M., 2002. Comparative study of extraction for determination of PAH from contaminated soils and sediments. Chemosphere. 48, 993–1001.
16. Rissanen T., Hyotylainen T., Kallio M., Kronholm J., Kulmala M., Riekkola M.L., 2006. Characterization of organic compounds in aerosol particles from a coniferousforest by GC–MS. Chemosphere. 64, 1185–95.
17. Wartel M., Pauwels J.F., Desgroux P., Mercier X., 2010. Quantitative measurement of naphthalene in low-pressure flames by jet-cooled laser-induced fluorescence. Appl Phys B. 100, 933–43.
18. Ballesteros R., Hernandez J.J., Lyons L.L., 2009. Determination of PAHs in diesel particulate matter using thermal extraction and solid phase micro-extraction. Atmos Environ. 43, 655–62.
19. Mastral A., Callen M., Murillo R., Garcia T., Vinas M., 1999. Influence on PAH emissions of the air flow in AFB coal combustion. Fuel. 78, 1553–7.
20. Aracil I., Font R., Conesa J.A., 2005. Semivolatile and volatile compound from the pyrolysis and combustion of polyvinyl chloride. J Anal Appl Pyrol. 74, 465–78.
21. Font R., Aracil I., Fullana A., Martin-Gullon I., Conesa J.A., 2003. Semivolatile compounds in pyrolysis of polyethylene. J Anal Appl Pyrol. 69, 599–611.
22. Ledesma E.B., Marsh N.D., Sandrowitz A.K., Wornat M.J., 2002. Global kinetic rate parameters for the formation of polycyclic aromatic hydrocarbons from the pyrolysis of catechol, a model compound representative of solid fuel moieties. Energy Fuel. 16, 1331–6.
23. Thomas S., Ledesma E.B., Wornat M.J., 2007. The effects of oxygen on the yields of thethermal decomposition products of catechol under pyrolysis and fuel rich oxidation conditions. Fuel. 86, 2581–95.
24. Mirabi A., Jamali M.R., Kazemi Q., 2016. Determination of trace amounts of manganese in water samples by flame atomic absorption spectrometry after dispersive liquid-liquid microextraction, Bulg Chem Commun. 48, 525-531.
25. Movaghgharnezhad Sh., Mirabi A., Toosi M.R., Shokuhi-Rad A., 2020. Synthesis of cellulose nanofibers functionalized by dithiooxamide for preconcentration and determination of trace amounts of Cd (II) ions in water samples, Cellulose. 27, 8885–8898.
26. Mirabi A., Dalirandeh Z., Shokuhi-Rad A., 2015. Preparation of modified magnetic nanoparticles as asorbent for the preconcentration and determination of cadmium ions in food and environmental water samples prior to flame atomic absorption spectrometry. J Magn Magn Mater. 381, 138-144.
27. Mirabi A., Shokouhi-Rad A., Nourani S., 2015. Application of Modified Magnetic Nanoparticles as a Sorbent for Preconcentration and Determination of Nickel Ions in Food and Environmental Water Samples. Trends Anal Chem. 74, 146-151.
28. Mirabi A., Shokuhi-Rad A., Jamali M.R., Danesh N., 2016. Use of Modified γ-Alumina Nanoparticles for the Extraction and Preconcentration of Trace Amounts of Cadmium Ions. Aust J Chem. 69, 314–318.
29. Li X.G., Feng H., Huang M.R., Gu G.L., Moloney M.G., 2012. Ultrasensitive Pb (II) potentiometric sensor based on copolyaniline nanoparticles in a plasticizer-free membrane with a long lifetime. Anal Chem. 84, 134-140.
30. Huang M.R., Ding Y.B., Li X.G., Liu Y., Xi K., Gao C.L., Kumar R.V., 2014. Synthesis of semiconducting polymer microparticles as solid ionophore with abundant complexing sites for long-life Pb(II) sensors, ACS appl mater interfaces. 6, 22096-22107.
31. Huang M.R., Ding Y.B., Li X.G., 2013. Lead ion potentiometric sensor based on electrically conducting microparticles of sulfonic phenylenediamine copolymer. Analyst. 138, 3820-3829.
32. Lam S.H., Chen C.K., Wang J.Sh., Lee Sh.Sh., 2008. Investigation of Flavonoid Glycosides from Neolitsea sericea var. auratavia the General Method and HPLC-SPE-NMR. J Chin Chem Soc. 55, 449-455.
33. Ghaedi M., Shokrollahi A., Ahmadi F., 2007. Simultaneous preconcentration and determination of copper, nickel, cobalt and lead ions content by flame aomic absorption spectrometry. J Hazard Mater. 142, 272-278.
34. Mirabi A., Shokuhi-Rad A., Khodadad H., 2015. Modified surface based on magnetic nanocomposite of dithiooxamide /Fe3O4 as a sorbent for preconcentration and determination of trace amounts of copper. J Magn Magn Mater. 389, 130-135.
35. Environmental Protection Agency, EPA. Compendium of methods for the determination of toxic organic compounds in ambient air, method TO-13A, EPA/625/R-96/010b. Ohio. 1999.