Influence of a transboundary emission on bioavailability of metals of stinging nettle from soil

• Autorzy: Kowol J. , Kwapulinski J. , Brodziak-Dopierala B. , Paukszto A. , Bogunia M. , Rochel R. , Ahnert B.
• Języki publikacji: EN

Abstrakty

EN

Bioavailability of individual chemical forms of metals occurring in soil is a basic source of its accumulation in plants. Soils from a root layer collected from the stands of stinging nettle Urtica dioica L., reflect different habitat conditions in the area of Wisła, a town in southern Poland. The Bukowa, Czarne, Głębce, Jawornik, Kubalonka, Malinka, Kobyla, and Salmopol also were research subjects. The content of the following metals in soils, as well as in fallout dust, was measured using the AAS method: Cd, Ni, Cr, Pb, Cu, Zn, Mn, and Fe. Accuracy was controlled by using CRM 277 and IAEA-SOIL-7 as reference materials. Speciation analysis in accordance with Rudd’s method allowed for evaluation of bioavailability of those metals in plants. The most bioavailable elements in an exchangeable form on all examined stands were Zn, Pb, Cu, and Cr resulting from a complex influence of transboundary emission, traffic emission, and low emission from coal combustion. Also organic bounds might be potentially bioavailable during acid rainfalls as well as carbonates of particular elements, and the biggest proportion was noticed for Zn, Pb, and Fe. It may result in a higher accumulation of those elements in medicinal plants that are collected in a natural state. The range of metal pseudo-total contents in soil in the area of Wisła was limited to the following values (mg・kg-1): Cd – 5.3-12.9, Cr – 4.7-14.2, Cu – 9.4-27.1, Ni – 8.2-18.5, Pb – 41.3-99.7, Zn – 106.7-480.6, Mn – 106.2-481.9, and Fe – 7,000.0-16,300.0.

• Wydawca: -
• Czasopismo: Polish Journal of Environmental Studies
• Rocznik: 2011
• Tom: 20
• Numer: 1
• Opis fizyczny: p.115-124,fig.,ref.

Twórcy

autor

Kowol J.

• Department of Toxicology, Medical University of Silesia, Jagiellonska 4, 41-200 Sosnowiec, Poland

autor

Kwapulinski J.

autor

Brodziak-Dopierala B.

autor

Paukszto A.

autor

Bogunia M.

autor

Rochel R.

autor

Ahnert B.

Bibliografia

• 1. SALEMAA M., DEROME J., HELMISAARI H., NIEMINEN T., VANHA-MAJAMAA I. Element accumulation in boreal bryophytes, lichenes and vascular plants exposed to heavy metal and sulphur deposition in Finland. Sci. Total Environ. 324, 141, 2004.
• 2. PARPAN V.I., SHPARYK Y.S. Heavy metal pollution and forest healt in the Ukrainian Carpathians. Environ. Pollut. 130, 55, 2004.
• 3. J.L. No. 60, item 311, 1985 [In Polish].
• 4. GRODZIŃSKA-JURCZAK M., GODZIK B. Air pollution and atmospheric precipitation chemistry in Poland – a review. Environ. Rev. 7, (2), 69, 1999.
• 5. MILL W. Transboudary air pollution with acidogenic substances with special regard to Silesia. Problemy Ekologii 8, 296, 2004 [In Polish].
• 6. HATTORI H. Decomposition of organic matter with previous cadmium adsorption in soil. Soil Sci. Plant Nutr. 42, 745, 1996.
• 7. CHŁOPECKA A. Forms of trace elements from inorganic sources in soil and amounts found in spring barley. Water, Air, Soil Pollut. 69, 127, 1993.
• 8. YONG R.N., GALVEZ-CLOUTIER R., PHADUNGCHEWIT Y. Selective sequential extraction analysis of heavy metals retention in soil. Can. Geoch. J. 30, 834, 1993.
• 9. IIN Q., ZI-JIAN W., XIAO-QUAN S., QIANG T., BEI W., BIN C. Evaluation of plant availability of soil trace metals by chemical fractionation and multiple regression analysis. Environ. Pollut. 91, 309, 1996.
• 10. TEMPLETON D. M., ARIESE F., CORNELIS R., DANIELSSON L. G., MUNTAU H., VAN LEEUWEN H. P., ŁOBIŃSKI R. Guidelines for terms related to chemical speciation and fractionation of elements. Definitions, structural aspects, and methodological approaches (IUPAC Recommendations 2000). Pure Appl. Chem. 72, 1453, 2000.
• 11. HLAVAY J., PROHASKA T., WEISZL M. WALTER W. W., STRINGEDER J. G. Determination of trace elements bound to soil and sediment fraction. Pure Appl. Chem. 76, 415, 2004.
• 12. RUDD T., LAKE D.L., MEHROTRA J., STERRITT R.M., KIRK P.W.W., CAMPBELL J.A., LESTER J.N. Characterisation of metal forms in sewage sludge by chemical extraction and progressive acidification. Sci. Total Environ. 74, 149, 1988.
• 13. SALMINEN R., BATISTA M.J., BIDOVEC M. Geochemical Atlas of Europe, Part 1 – Background Information, Methodology and Maps. Geological Survey of Finland, Espoo. http//gtk/publ/foregsatlas, 2005.
• 14. IUSS Working Group WRB. World reference base for soil resources 2006. World Soil Resources Reports 103, FAO, Rome, 2006.
• 15. BURCZYK J., WIECHUŁA D., MIROSŁAWSKI J., DORDA E., PAUKSZTO A., ROCHEL R., KWAPULIŃSKI J. The plants' contamination in range of industrial emission on example of Cieszyn. Ochr. Pow. I Probl. Odpadow 4, 124, 1996 [In Polish].
• 16. MIROSŁAWSKI J., KWAPULIŃSKI J., KOWOL J., WIECHUŁA D., PAUKSZTO A., ROCHEL R. Speciation of Pb in soil. Zesz. Nauk. Komitetu “Człowiek i Środowisko PAN 21, 79, 1998 [In Polish].
• 17. LIS J., PASIECZNA A. Geochemical Atlas of Upper Silesia. Państwowy Instytut Geologiczny, Warszawa, 1995 [In Polish].
• 18. KOWOL J., KWAPULIŃSKI J., PAUKSZTO A., GROMULSKA E., GOSZYK E. Concentration of heavy metals in the dust deposited on the coltsfoot and stinging nettle leaves in the Vistula area Pol. J. Environ. Stud. 15, (2A), 381, 2006.
• 19. REIMANN C., GARRETT R.G. Geochemical background – concept and reality. Sci. Tot. Environ. 350, 12, 2005.
• 20. GAŁUSZKA A. A review of geochemical background concept and an example using data from Poland. Environ. Geol. 52, 861, 2007.
• 21. KARCZEWSKA A., SZOPKA K., KABAŁA C., BOGACZ A. Zinc and lead in forest soil of Karkonosze National Park – data for assessment of environmental pollution and soil monitoring. Pol. J. Environ. Stud. 15, (2A), 336, 2006.
• 22. ERNST W.H.O. Bioavailability of heavy metals and decontamination of soil by plants Appl. Geochem. 11, 163, 1996.
• 23. FAIRBROTHER A., WENSTEL R., SAPPINGTON K., WOOD W. Framework for Metals Risk Assessment. Ecotox. Environ. Safe. 68, 145, 2007