Spatial distribution and reduction of PCDD/PCDF Toxic Equivalents along three shallow lowland reservoirs
| dc.contributor.author | Urbaniak, M. | |
| dc.contributor.author | Kiedrzyńska, Edyta | |
| dc.contributor.author | Zieliński, M. | |
| dc.contributor.author | Tołoczko, Wojciech | |
| dc.contributor.author | Zalewski, Maciej | |
| dc.date.accessioned | 2015-08-28T10:01:31Z | |
| dc.date.available | 2015-08-28T10:01:31Z | |
| dc.date.issued | 2013-12-12 | |
| dc.identifier.issn | 1614-7499 | |
| dc.identifier.uri | http://hdl.handle.net/11089/11587 | |
| dc.description.abstract | Reservoirs situated along a river continuum are ecosystems where rates of transfer of suspended matter and associated micropollutants are reduced due to sedimentation, accumulation, and biological and physical transformation processes. Among the micropollutants, PCDDs and PCDFs are substances that are highly toxic and carcinogenic for humans and animals. They are emitted and dispersed in the environment throughout the whole catchment area and may accumulate in aquatic and terrestrial food chains, creating a risk for human health. A wealth of data exists indicating the increase in the concentrations of pollutants along a river continuum. A comparative analysis of total, individual, and TEQ PCDD/PCDF concentrations in large lowland, shallow reservoirs located in different catchments (“I”—industrial/urban/ agricultural, “U”—urban/agricultural, and “A”—agricultural/ rural) showed decreases of the TEQ concentrations in bottom sediments along a gradient from the middle sections to the dam walls. Moreover, penta-, hexa-, and heptachlorinated CDD/CDF congeners were reduced from 28.8 up to 93.6 % in all three types of reservoirs. A further analysis of water samples from the inlets and outlets of the “A” reservoir confirmed this tendency. | pl_PL |
| dc.description.sponsorship | The authors wish to express their sincere appreciation to Prof. Konrad Rydzyński from the Nofer Institute of Occupational Medicine in Lodz, Prof. Richard Robarts from the UNEP Global Environment Monitoring System (GEMS)/Water Programme, Prof. Paul DuBowy from the U.S. Army Corps of Engineers, and Prof. David Harper from the Department of Biology, the University of Leicester for their constructive comments on an earlier version of this paper. The authors also wish to acknowledge the research team of the Nofer Institute of Occupational Medicine in Lodz: Dr Danuta Ligocka and Dr Wiktor Wesołowski for their assistance during the laboratory processes. The research was supported by the following projects of the Polish Ministry of Science and Higher Education: – N N305 365738 “Analysis of point sources pollution of nutrients, dioxins and dioxin-like compounds in the Pilica River catchment and draw up of reclamation methods”; – 2PO4 G08830 “Accumulation of dioxins and dioxin-like pollutants in the food chain of the Sulejowski and Włocławski Reservoirs: chemometric analysis and toxicological estimation”. | pl_PL |
| dc.language.iso | en | pl_PL |
| dc.publisher | Springer Berlin Heidelberg | pl_PL |
| dc.relation.ispartofseries | Environmental Science and Pollution Research;21 | |
| dc.rights | Uznanie autorstwa 3.0 Polska | * |
| dc.rights.uri | http://creativecommons.org/licenses/by/3.0/pl/ | * |
| dc.subject | PCDDs/PCDFs | pl_PL |
| dc.subject | Sediments | pl_PL |
| dc.subject | Toxicity reduction | pl_PL |
| dc.subject | Reservoir | pl_PL |
| dc.title | Spatial distribution and reduction of PCDD/PCDF Toxic Equivalents along three shallow lowland reservoirs | pl_PL |
| dc.type | Article | pl_PL |
| dc.page.number | 4441–4452 | pl_PL |
| dc.contributor.authorAffiliation | Department of Applied Ecology, Faculty of Biology and Environmental Protection, University of Lodz, European Regional Centre for Ecohydrology, Polish Academy of Sciences | pl_PL |
| dc.contributor.authorAffiliation | Department of Applied Ecology, Faculty of Biology and Environmental Protection, University of Lodz, European Regional Centre for Ecohydrology, Polish Academy of Sciences | pl_PL |
| dc.contributor.authorAffiliation | Department of Physical Geography, Faculty of Geography, University of Lodz | pl_PL |
| dc.contributor.authorAffiliation | Department of Applied Ecology, Faculty of Biology and Environmental Protection, University of Lodz, European Regional Centre for Ecohydrology, Polish Academy of Sciences | pl_PL |
| dc.contributor.authorAffiliation | Nofer Institute of Occupational Medicine | pl_PL |
| dc.references | Allock RE, Jones KC (1997) Pentachlorophenol (PCP) and chloranil as PCDD/Fs sources to sewage sludge and sludge amended soils in UK. Chemosphere 35:2317–2330 | pl_PL |
| dc.references | Ambrożewski Z (1993) Designing and implementation of Sulejów reservoir. Gospodarka. Wodna 12:267–273 [in Polish] | pl_PL |
| dc.references | Ambrożewski Z (1996) Environmental problems and flooding in Sulejow Reservoir. Aura 7:19–21 [in Polish] | pl_PL |
| dc.references | Bielecka E, Ciołkosz A (2004) CORINE land cover 2000 in Poland. Final report. Institute of Geodesy and Cartography. Warszawa (http://igik. edu.pl/clc_final_report_pl.pdf) | pl_PL |
| dc.references | Bostian K, Merechal AM, Voncina E, Bronijak-Voncina D (2004) Textile dyes and pigments as a source of dioxins. Organochalogen Comp 66:931–935 | pl_PL |
| dc.references | Bowes MJ, House WA, Hodgkinson RA (2003) Phosphorus dynamics along a river continuum. Sci Total Environ 313:199–212 | pl_PL |
| dc.references | Bunge M, Lechner U (2009) Anaerobic reductive dehalogenation of polychlorinated dioxins. Appl Microbial Biotechnol 84:429–444 | pl_PL |
| dc.references | Camusso M, Vignati D, Van De Guchte C (2000) Ecotoxicological assessment in the rivers Rhine (The Netherlands) and Po (Italy). Aquat Ecosys Health Manag 3:335–345 | pl_PL |
| dc.references | Chi KH, Chang MB, Kao SJ (2007) Historical trends of PCDD/Fs and dioxin-like PCBs in sediments buried in a reservoir in Northern Taiwan. Chemosphere 68:1733–1740 | pl_PL |
| dc.references | Chi KH, Hsu S-C, Lin C-Y, Kao SJ, Lee TY (2011) Deposition fluxes of PCDD/Fs in a reservoir system in northern Taiwan. Chemosphere 83:745–752 | pl_PL |
| dc.references | Devault DA, Gerino M, Laplanche C, Julien F, Winterton P, Merlina G, Delams F, Sanches-Perez JM, Pinelli E (2009) Herbicide accumulation and evolution in reservoir sediments. Sci Total Environ 407: 2659–2665 | pl_PL |
| dc.references | Field JA, Sierra-Alvarez R (2008) Microbial degradation of chlorinated dioxins. Chemosphere 71:1005–1018 | pl_PL |
| dc.references | Galicka W (1996) Limnological characteristics of lowland dam reservoir on Pilica in the years 1981–1993. Faculty of Biological Sciences, University of Lodz, Habilitation Thesis | pl_PL |
| dc.references | Galicka W, Kruk A, Zięba G (2007) The balance of nitrogen and phosphorus in the Jeziorsko Reservoir. Science Nature and Technologies 1:2 | pl_PL |
| dc.references | Gihr R, Klopffer W, Rippen G, Partscht I (1991) Investigations on potential sources of polychlorinated dibenzo-p-dioxins and dibenzofurans in sewage sludges. Chemosphere 23:1653–1659 | pl_PL |
| dc.references | Greenberg AE, Clesceri LS, Eaton AD (1992) Standard methods for the examination of water and wastewater. American Public Health Association, Washington | pl_PL |
| dc.references | Grzesiak M, Domańska W (2006) Environmental protection 2006. Information and statistical papers, GUS, Warsaw | pl_PL |
| dc.references | Hilscherova K, Kannan K, Nakata H, Yamashita N, Bradley P, Maccabe JM, Taylor AB, Giesy JP (2003) Polychlorinated dibenzo-p-dioxin and dibenzofuran concentration profiles in sediments and floodplain soils of the Tittabawssee River, Michigan. Environ Sci Technol 37:468–474 | pl_PL |
| dc.references | Hu W-W, Wang G-X, Deng W, Li S-N (2008) The influence of dams on ecohydrological conditions in the Huaihe River basin, China. Ecol Eng 33:233–241 | pl_PL |
| dc.references | Kannan K, Kober JL, Kang YS, Masunaga S, Nakanishi J, Ostaszewski A, Giesy JP (2001) Polychlorinated naphtalens, -biphenyls, -dibenzo-pdioxins, -dibenzofurans, polycyclic aromatic hydrocarbons and alcylphenols in sediment from the Detroit and Rouge Rivers, Michigan, USA. Environ Toxicol Chem 20:1878–1889 | pl_PL |
| dc.references | Kentzer A, Dembowska E, Gizinski A, Napiorkowski P (2010) Influence of the Włocławek Reservoir on hydrochemistry and plankton of a large, lowland river (the Lower Vistula River, Poland). Ecol Eng 36: 1747–1753 | pl_PL |
| dc.references | Kiedrzyńska E, Wagner-Łotkowska I, Zalewski M (2008a) Quantification of phosphorus retention efficiency by floodplain vegetation and a management strategy for a eutrophic reservoir restoration. Ecol Eng 33:15–25 | pl_PL |
| dc.references | Kiedrzyńska E, Kiedrzyński M., Zalewski M (2008b). Flood sediment deposition and phosphorus retention in a lowland river floodplain: impact on water quality of a reservoir, Sulejów, Poland. Ecohydr Hydrobiol 8:281–289 | pl_PL |
| dc.references | Klanowa J, Matykiewiczova N, Zdenek M, Prosek P, Laska K, Klan P (2007) Persistent organic pollutants in soils and sediments from James Ross Island, Antarctica. Environ Pollut 152:416–423 | pl_PL |
| dc.references | Koh CH, Khim JS, Kannan K, Villeneuve DL, Senthilkumar K, Giesy JP (2004) Polichlorinated dibenzo-p-dioxins (PCDDs), dibenzofurans (PCDFs), biphenyls (PCBs), and polycyclic aromatic hydrocarbons (PAHs) and 2,3,7,8-TCDD equivalents (TEQs) in sediments from the Hyeongsan River, Korea. Environ Poll 123:489–501 | pl_PL |
| dc.references | Konieczka P, Lisinger TP, Zygmunt B, Namiesnik J (2005) Determination of PCBs in river sediment samples—proficiency test for selected Polish laboratories. Accred Dual Asur 10:241–251 | pl_PL |
| dc.references | Kowalewska G, Konat-Stepowicz J, Wawrzyniak-Wydrowska B, Szymczyk-Żyla M (2003) Transfer of organic contaminants to the Baltic in the Oder Estuary. Mar Pollut Bull 46:703–718 | pl_PL |
| dc.references | Krasa J, Dostal T, Van Rompaey A, Vaska J, Vrana K (2005) Reservoirs' siltation measurements and sediment transport assessment in the Czech Republic, the Vrchlice catchment study. Catena 64:348– 362 | pl_PL |
| dc.references | Kuligowski A (2007) Usage Jeziorsko Reservoir for fishing and angling—shape the structure of fish fauna in the years 1988–2006. Science Nature and Technologies 1:2 | pl_PL |
| dc.references | Lexen K, de Wit C, Jansson B, Kieller L-O, Kulp SE, Ljung K, Soderstrom Rappe C (1993) Polychlorinated dibenzo-p-dioxin and dibenzofuran levels and patterns in samples from different Swedish industries analyzed within the Swedish dioxin survey. Chemosphere 27:163–170 | pl_PL |
| dc.references | Li Q, Yu M, Lu G, Cai T, Bai X, Xia Z (2011) Impacts of the Gezhouba and Three Gorges reservoirs on the sediment regime in the Yangtze River, China. J Hydrology 403:224–233 | pl_PL |
| dc.references | Liu F, Fennell DE (2008) Dechlorination and detoxification of 1,2,3,4,7, 8-hexachlorodibenzofuran by a mixed culture containing Dehalococcoides ethenogenes strain 195. Environ Sci Technol 42: 602–607 | pl_PL |
| dc.references | Lizak R, Rachubik J, Piskorska-Pliszczynska J, Kowalski B (2005) Analysis of PCDD and PCDF in animal feeding stuffs by HRGC/HRMS using isotope dilution technique. VII Scientific Conference: dioxins in industry and environment, 16–17.VI.2005, Kraków-Tomaszowice | pl_PL |
| dc.references | Lohman R, Brevik K, Dachs J, Muir D (2007) Global fate of POPs: current and future research directions. Environ Pollut 150:150–155 | pl_PL |
| dc.references | Miller G T Jr (2005) Environmental science, 5th edn. Belmont, Wadsworth | pl_PL |
| dc.references | Nam IH, Kim YM, Schmidt S, Chang YS (2006) Biotransformation of 1, 2,3-tri- and 1,2,3,4,7,8-hexachlorodibenzo-p-dioxin by Sphingomonas wittichii strain RW1. Appl Environ Microbol 70: 112–116 | pl_PL |
| dc.references | Niemirycz E, Jankowska D (2011) Concentrations and profiles of PCDD/Fs in sediments of major Polish rivers and the Gdansk Basin—Balic Sea. Chemosphere 85:525–532 | pl_PL |
| dc.references | Nieuwoudt C, Quinn LP, Pieters R, Jordan I, Visser M, Kylin H, Bergen AR, Giesy JP, Bouwman H (2009) Dioxin-like chemicals in soil and sediment from residential and industrial areas in Central South Africa. Chemosphere 76:774–783 | pl_PL |
| dc.references | Ostrowska A, Gawliński S, Szczubiałka Z (1991) Method of analysis and estimate soil and plants property. Catalogue of the Environmental Protection Institute, Warsaw, Poland, 334 | pl_PL |
| dc.references | Piskorska-Pliszczyńska J, Małagocki P, Gembal M, Stypuła-Trebas S, Lizak R, Warenik-Bany M, Maszewski S (2008) The content of dioxins and dl-PCBs in feeding stuffs based on national surveys in 2004–2007. IX Scientific Conference Dioxins in industry and environment 12-13.VI.2008, Kraków-Tomaszowice | pl_PL |
| dc.references | PN-EN 1948-2 (2002) Emission from stationary sources. Determination of PCDD/PCDF mass concentration. PRT 3: Identification and quantification [In Polish] | pl_PL |
| dc.references | Ran L, Lu XX, Xin Z, Yang X (2013) Cumulative sediment trapping by reservoirs in large river basins: a case study of the Yellow River basin. Glob Planet Chang 100:308–319 | pl_PL |
| dc.references | Szyper H, Mastyński J (1997) Lowland dam reservoir Jeziorsko. Aura 8: 19–21 [In Polish] | pl_PL |
| dc.references | Tamm H, Łapińska M, Zalewski M, Osauskyte V, Skorupskas R, Briede A, Druvitis I, Gavrilova G, Parele E, Springe G, Gaumiga R, Melnik MM, Aleksandrov JV (2009) Baltic and eastern continental rivers. Chapter 16. 607-642 [In:] Tockner K, Robinson ChT, Uehlinger U (Eds.) Rivers of Europe | pl_PL |
| dc.references | Urbaniak M (2013) Biodegradation of PCDDs/PCDFs and PCBs. Chapter 4. 73-100 [In:] Chamy R and Rosenkrantz F (Eds.) Biodegradation—engineering and technology. InTech, Rijeka | pl_PL |
| dc.references | Urbaniak M, Zieliński M, Wesołowski W, Zalewski M (2008) PCBs and heavy metals contamination in bottom sediments from three reservoirs of different catchment characteristics. Pol J Environ Stud 17: 941–949 | pl_PL |
| dc.references | Urbaniak M, Zieliński M, Wesołowski W, Zalewski M (2009a) Sources and distribution of polychlorinated dibenzo-para-dioxins and dibenzofurans in sediments of urban cascade reservoirs, Central Poland. Environ Protec Engineer 3:93–103 | pl_PL |
| dc.references | Urbaniak M, Zieliński M, Wesołowski W, Zalewski M (2009b) Polychlorinated dibenzo-p-dioxins (PCDDs) and polychlorinated dibenzo-p-furans (PCDFs) compounds in sediments of two shallow reservoirs in Central Poland. Arch Environ Protec 35:125–132 | pl_PL |
| dc.references | Urbaniak M, Skowron A, Fratczak W, Zieliński M, Wesołowski W (2010a) Transport of polychlorinated biphenyls in urban cascade reservoirs: levels, sources and correlation to the environmental conditions. Pol J Environ Stud 19:201–211 | pl_PL |
| dc.references | Urbaniak M, Zieliński M, Ligocka D, Zalewski M (2010b) The comparative analysis of selected persistent organic pollutants (POPs) in reservoirs of different types of anthropopression—Polish and Ethiopian studies. Fresenius Environ Bull 19:2710–2718 | pl_PL |
| dc.references | Urbaniak M, Skowron A, Zieliński M, Zalewski M (2012a) Hydrological and environment al conditions as key drivers for spatial and seasonal changes in PCDD/PCDF concentrations, transport and deposition along urban cascade reservoirs. Chemosphere 88:1358– 1367 | pl_PL |
| dc.references | Urbaniak M, Kiedrzyńska E, Zalewski M (2012b) The role of a lowland reservoir in the transport of micropollutants, nutrients and the suspended particulate matter along the river continuum. Hydrol Res 43:400–411 | pl_PL |
| dc.references | Urbaniak M, Zieliński M, Kaczkowski Z, Zalewski M (2013) Spatial distribution of PCDDs, PCDFs and dl-PCBs along the cascade of urban reservoirs. Hydrol Res 44:614–630 | pl_PL |
| dc.references | Vannote RL, Minshall GW, Cummings KW, Sedell JR, Cushing CE (1980) The river continuum concept. Canad J Fish Aquati Sci 37: 130–137 | pl_PL |
| dc.references | Wagner I, Zalewski M (2000) Effect of hydrological patterns of tributaries on processes in a lowland reservoir—consequence of restoration. Ecol Eng 16:79–90 | pl_PL |
| dc.references | Ward JV, Stanford JA (1983) The serial discontinuity concept of lotic ecosystems. [In:] Fontaine TD and Bartell SM (eds) Dynamics of lotic ecosystems. Ann Arbor Science 29–42 | pl_PL |
| dc.references | WCD World Commission on Dams (2000) Dams and development: a new framework for decision-making. Earthscan, London | pl_PL |
| dc.references | Zalewski M (2010) Ecohydrology for compensation of global change. Braz J Biol 70:689–695 | pl_PL |
| dc.references | Zhai H, Cui B, Hu B, Zhang K (2010) Prediction of river ecological integrity after cascade hydropower dam construction on the mainstream of rivers in Longitudinal Range-Gorge Region (LTGR), China. Ecol Eng 36:361–372 | pl_PL |
| dc.contributor.authorEmail | m.urbaniak@unesco.lodz.pl | pl_PL |
| dc.identifier.doi | 10.1007/s11356-013-2401-7 |
Pliki tej pozycji
Pozycja umieszczona jest w następujących kolekcjach
Poza zaznaczonymi wyjątkami, licencja tej pozycji opisana jest jako Uznanie autorstwa 3.0 Polska