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Magdalena Senze and Monika Kowalska-Góralska

2011, No. 257, pos.1545). Neal C., Williams R.J., Neal M., Bhardwaj L.C., Wickham H., Harrow M., Hill L.K., 2000, The water quality of the River Thames at a rural site downstream of Oxford, Sci. Total Environ. 251/252, 441-457. Oberholster P.J., Myburgh J. G., Ashton P.J., Coetzee J.J., Botha A-M., 2012, Bioaccumulation of aluminium and iron in the food chain of Lake Loskop South Africa, Ecotoxicol. Environ. Saf. 75(1): 134-141. PB-10/I - Procedura badawcza. Metody analityczne firmy VARIAN (Test procedure. Analytical methods of VARIAN). [PKN] Polski Komitet

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Linda Machalová, Martin Pipíška, Zuzana Trajteľová and Miroslav Horník

References ADAM, V., CHUDOBOVA, D., TRNEJOVA, K., CIHALOVA, K., KRIZKOVA, S., GURAN, R., KOMINKOVA, M., ZUREK, M., KREMPLOVA, M., JIMENEZ, A.M.J., KONECNA, M., HYNEK, D., PEKARIK, V., KIZEK, R.: An effect of cadmium and lead ions for methallothionein (MT-3) revealed by electrochemistry. Electrochim. Acta, 140, 2014, 11-19. ALAM, M.Z., AHMAD, S.: Multi-metal biosorption and bioaccumulation by Exiguobacterium sp. ZM-2. Ann. Microbiol., 63, 2013, 1137-1146. BESTAWY, E.E., HELMY, S., HUSSEIN, H., FAHNY, M., AMER, R.: Bioremediation of heavy metal

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Simona Kvasnová, Ľudmila Hamarová and Peter Pristaš

References Ahmed MJ, Alam M (2003) A rapid spectrophotometric method for the determination of mercury in environmental, biological, soil and plant samples using diphenylthiocarbazone. Spectroscopy 17: 45-52. Alvarez A, Saez JM, Costa JSD, Colin VL, Fuentes, MS, Cuozzo SA, Amoroso MJ (2017) Actinobacteria: Current research and perspectives for bioremediation of pesticides and heavy metals. Chemosphere 166: 41-62. Boriová K, Urík M, Matus P (2015) Biosorption, bioaccumulation, biovolatilization of potentially

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Vesela Yancheva, Stela Stoyanova, Iliana Velcheva, Slaveya Petrova and Elenka Georgieva

References 1. Sekabira K, Oryem Origa H, Basamba TA, Mutumba, G, Kakudidi E. Assessment of heavy metal pollution in the urban stream sediments and its tributaries. Int J Environ Sci Technol 2010;7:435-46. doi: 10.1007/BF03326153 2. Carrasco L, Benejam L, Benito J, Bayona JM, Díez S.Methylmercury levels and bioaccumulation in the aquatic food web of a highly mercury-contaminated reservoir.Environ Int 2011;37:1213-8. doi: 10.1016/j. envint.2011.05.004 3. Kumar B, Sajwan KS, Mukherjee DP. Distribution of heavy

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Ewa Możdżer, Krystyna Cybulska, Teresa Krzyśko-Łupicka and Edward Meller

Abstract

Therefore the carried out study aimed at determination of the effect of high-calcium brown coal ash and compost being produced from municipal sewage sludge on the content and bioaccumulation of heavy metals in potato tubers, wheat grains and rapeseeds during a three-year period. Rapeseeds contained most Cd whereas wheat rains less. Potato tubers, wheat grains and rapeseeds contained more Mn, Ni and Zn in the fertilization objects with municipal sewage sludge with or without coal ash and compared to those where calcium carbonate or coal ash had been introduced into the soil at a dose corresponding to 1.5 Mg CaO · ha–1 at the beginning of this study. Differences in the Mn, Ni and Zn contents in test plants between the fertilization objects with sewage sludge of with and without addition of ash were not significant.

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Mojtaba Taran, Mazyar Safari, Arina Monaza, Javad Zavar Reza and Salar Bakhtiyari

& Research 18: 264-268. 16. Srinath, T., Verma, T., Ramteke, P.W. & Garg, S.K. (2002). Chromium(VI) biosorption and bioaccumulation by chromate resistant bacteria. Chemosphere 48: 427-435. http://dx.doi.org/10.1016/S0045-6535(02)00089-9. 17. Takeuchi, M., Kawahata, H., Gupta, L.P., Kita, N., Morishita, Y., Ono, Y. & Komai, T. (2007). Arsenic resistance and removal by marine and non-marine bacteria. Journal of Biotechnology 127: 434-442. http://dx.doi.org/10.1016/j.jbiotec.2006.07.018. 18. Srivastava, P.K., Vaish, A., Dwivedi

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Ewa Krzywy-Gawrońska

A single-factor field experiment was carried out at the Cultivar Evaluation Station in Szczecin-Dąbie in 2008-2010. In the experiment, the compost produced with municipal sewage sludge by the GWDA method and high-calcium brown coal ash (furnace waste) were used. The perennial energy crop was a test plant - Virginia fanpetals (Sida hermaphrodita Rusby). It results from the carried out study that Virginia fanpetals biomass contained on average the most manganese (24.7 mg∙kg-1 d.m.), lead (2.50 mg∙kg-1 d.m.) and zinc (50.5 mg∙kg-1 d.m.) in 2008, while the most cadmium (0.33 mg∙kg-1 d.m.), copper (3.78 mg∙kg-1 d.m.) and nickel (2.57 mg∙kg-1 d.m.) in 2010. Average cadmium, copper, manganese, nickel, lead and zinc contents in test plant biomass were higher, respectively by 14.3%, 10.0%, 7.3%, 19.3%, 29.1% and 6.9%, in the objects where municipal sewage sludge compost had been applied without and with addition of high-calcium brown coal ash when compared to those where only calcium carbonate or high-calcium brown coal ash had been introduced into the soil. The differences in cadmium, copper, manganese, nickel, lead and zinc contents in Virginia fanpetals biomass between particular experimental objects were not signifi cant. The least zinc was absorbed by the test plant biomass in the object with high-calcium brown coal ash being applied in the fi rst year of study and annually. When evaluating the dynamics of heavy metals uptake, it was found to be the lowest in the fi rst year of study (ranging from 4.40% to 11.0%). It increased in the second and the third year of study, oscillating between 29.9% and 65.7%. The degree of heavy metals accumulation in Virginia fanpetals biomass differed, depending on the fertilisation applied. The bioaccumulation factor of cadmium, copper and nickel after three study years was average, while that of manganese, lead and zinc was intense.

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Przemysław Pokorny, Joanna Pokorny, Wojciech Dobicki, Magdalena Senze and Monika Kowalska-Góralska

., Robson, A.J., Wass, P., Wade, A.J., Ryland, G.P., Leach, D.V. & Leeks, G.J.L. (1998). Major, minor, trace element and suspended sediment variations in the River Derwent, The Science of the Total Environment , 210–211, pp. 163–172. Pokorny, P., Senze, M., Dobicki, W., Kowalska-Góralska, M. & Polechoński, R. (2013). Geochemical assessment of Western Pomerania watercourses, Przemysł Chemiczny , 92, pp. 1768–1771. (in Polish) Samecka-Cymerman, A. & Kempers, A.J. (1996). Bioaccumulation of heavy metals by aquatic macrophytes around Wrocław, Poland

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Oľga Šestinová, Jozef Hančuľák and Tomislav Špaldon

References Coelho C, Foret C, Bazin C, Leduc L, Hammada M, Inácio M, Bedell JP (2018) Bioavailability and bioaccumulation of heavy metals of several soils and sediments (from industrialized urban areas) for Eisenia fetida . Sci. Total. Environ. 635: 1317-1330. Dai J, Becquer T, Rouiller JH, Reversat G, Bernhard-Reversat F, Nahmani J, Lavelle P (2004) Heavy metal accumulation by two earthworm species and its relationship to total and DTPA-extractable metals in soils. Soil Biol. Biochem. 36, 91-98. Das KS, Chakrapani GJ (2011) Assessment of trace

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Anna Hołda

and Microbial Technology , 41, 51-56. [8] Bai, R.S., & Abraham, T.E. (2003). Studies on chromium (VI) adsorption-desorption using immobilized fungal biomass, Bioresour Technol ., 87, 17-26. [9] Srinath, T., Verma, T., Ramteka, P.W., & Garg, S.K. (2002). Chromium(VI) biosorption and bioaccumulation by chromate resistant bacteria, Chemophere , 48, 427-35. [10] Dursan, A.Y., Ulsu, G., Cuci Y., & Aksu Z. (2003). Bioaccumulation of copper(II), lead(II) and chromium(VI) by growing Aspergillus niger, Process Biochem ., 38