Metals phytotoxicity assessment and phyto maximum allowable concentration

Nataliia Olexandraivna Ryzhenko

Abstract


In this paper, the influence of metals (Cd, Pb, Cu, Co, Ni, Zn) on plants of spring barley (Hordeum vulgare L.) was investigated in polluted sod podzolic sandy loam on layered glacial sands and calcareous deep chernozem on loamy loess soils. We propose to highlight the metals’ phytotoxicity with help of the phyto maximum allowable concentration. The Phyto Maximum Allowable Concentration is a permissible level of metals for plants in polluted soil and represents the safe degree for plants in contaminated ecosystem. The phyto maximum allowable concentration gives the possibility to estimate and to forecast the danger of metals for plants as a biological object that plays a very important role in the life of ecosystem. This approach may be applied for another metals phytotoxicity assessment for other plants.


Keywords


trace metals (Cd, Pb, Cu, Co, Ni, Zn), phytotoxicity assessment, spring barley, phyto maximum allowable concentration

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References


Alloway, B., 2010. Heavy Metals in Soils. Trace Elements and Metalloids in Soils and Their Bioavailability. Springer, London, 235 pp.

Bradl, H., 2005. Heavy Metals in the Environment: Origin, Interaction and Remediation. Academic Press, Neubrücke, 282 pp.

Dospekhov, B., 1985. Methodology of Field Experiment. Agropromizdat, Мoscow, 415 pp. (in Russian).

Gill, M., 2014. Heavy metal stress in plants: A review. International Journal of Advanced Research, 2(6): 1043–1055.

Globally Harmonized System of Classifiation and Labelling of Chemicals (GHS), fourth revised version, 2011. United Nations, New York–Geneva, 568 pp.

Gorodniy, M., 2008 Agrochemistry, Ariste, Kyiv, 523 pp. (in Ukrainian).

Guidance Document on Statistical Methods for Environmental Toxicity Tests/ [issued by] Method Development and Applications Section, Environmental Technology Centre, Environment Canada, 2005, 113 pp.

Gyuricza, V., Fodor, F., Szigeti, Z., 2010. Phytotoxic effects of heavy metal contaminated soil reveal limitations of extract-based ecotoxicological tests. Water, Air, & Soil Pollution, 210(1–4): 113–122.

Kabata-Pendias, A., Mukherjee, A., 2007. Trace Elements from Soil to Human. SpringerVerlag, Berlin–Heidelberg, 550 pp.

Kavetsky, V., Makarenko, N., Buogis, A., Kavetsky, S., 2001. Thin layer chromatography methods of the Hg, Zn, Co, Cd, Cu, Ni determination in soil, plant and water. Ministry of Environment and Nature Protection of Ukraine, Kyiv, no. 50–97: 18–23 (in Ukrainian).

Lewis, R.A., 1998. Lewis’ Dictionary of Toxicology, CRC Press, USA, 1136 pp.

Mamatha, P., Salamma, S., Swamy, A.V.N., Rao, P., 2014. Quantitative and risk analysis of heavy metals in selected leafy vegetables. Der Pharma Chemica, 6(3): 179–185.

Medvedev, V., Laktionova, T., Bal’uk, S., Blokhina, N., Bililypsky, V., 1998. Method of Monitoring of Lands Which Are in the Crisis State. O.N. Sokolovsky’ Institute of Soil Science, Kharkiv, 88 pp. (in Ukrainian).

Nagajyoti, P., Lee, K., Sreekanth, T., 2010. Heavy metals, occurrence and toxicity for plants: A review. Environmental Chemistry Letters, 8: 199–216.

Rand, G., 1994. Fundamentals of Aquatic Toxicology. CRC Press, Boca Raton, 943 pp.

Rombke, J., Moltmann, J., 1996. Applied Ecotoxicology. Lewis Publishers, Boca Raton, 234 pp.

Ryzhenko, N., 2017. Principles of phytotoxicological normalization of metals. Bulletin of the Kremenchug National University named after Mikhail Ostrogradsky, 4(105): 96–102 (in Ukrainian).

Ryzhenko, N., Kavetsky, V., 2017. Probit analysis for Cd, Pb, Cu, Zn phytotoxicity assessment. Biotechnologia Acta, 10(2): 67–74.

Ryzhenko, N., Kavetsky, S., Kavetsky, V., 2017a. Cd, Zn, Cu, Pb, Co, Ni phytotoxicity assessment as function of its substance polarity shift. International Journal of Bioorganic Chemistry. 2: 163–173.

Ryzhenko, N., Kavetsky, S., Kavetsky, V., 2017b. Cd, Zn, Cu, Pb, Co, Ni phytotoxicity assessment. Polish Journal of Soil Science, L(2): 197–215.

Sardar, K., Ali, S., Hameed, S., 2013. Heavy metals contamination and what are the impacts on living organisms. Greener Journal of Environmental Management and Public Safety, 2(4): 172–179.

Satpathy, D., Reddy, V., Dhal, S., 2014. Risk assessment of heavy metals contamination in paddy soil, plants, and grains (Oryza sativa L.) at the East Coast of India. BioMed Research International, 2014: 1–11.

Smirnov, V., Maymulov, V., Nechiporenko, S., 2002. Estimated Methods for Hazard Assessment and Hygienic Evaluation of Harmful Substances in Environments. Foliant, St. Petersburg, 130 pp. (in Russian).

Tangahu, B., Abdullah, S., Basri, H., 2011. A review on heavy metals (As, Pb, and Hg) uptake by plants through phytoremediation. International Journal of Chemical Engineering, 2011: 1–32.

Warne, M., van Dam, R., 2008. NOEC and LOEC data should no longer be generated or used? Аustralasian Journal of Ecotoxicology, 14: 1–5.




DOI: http://dx.doi.org/10.17951/pjss.2019.52.1.165
Date of publication: 2019-06-24 09:00:44
Date of submission: 2018-09-14 07:50:58


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