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The problem of soil contamination is relevant today. Soil contamination is generally associated with intensive industrial activities, inadequate waste management, mining, military activities, or accidents. Pollutants (e.g. heavy metals) are accumulating in soil and have major indirect impacts on biodiversity, quality of groundwater resources, and food safety. Soil contamination of agricultural land is a particular threat. Due to the military action and other conditions, the numbers of sites where potentially polluting activities have taken place are increasing in Ukraine. The cultivation of agricultural crops on soils with a medium or high level of toxicity is only possible after the remediation of this area. The use of biological methods to intensify soil remediation processes, thereby reducing the additional burden on the environment, is becoming more widespread. The application of probiotics is an innovative and ecological method for the restoration of contaminated soils. This will enable to improve the conceptual approaches to the implementation of an ecologically safe model for the restoration of contaminated land under the conditions of military action in Ukraine. The aim of the research was to assess the phytotoxic effect of soil contaminated with heavy metals and petroleum products before and after probiotic application. The seedling method was used to determine the remediation potential of contaminated soils. An express test of Triticum aestivum was used to determine soil phytotoxicity. The research results show the negative impact of soil contamination with heavy metals and petroleum products on the biometric indices of Triticum aestivum plants and positive dynamics of biometric indices of Triticum aestivum in variants after probiotic treatment (86–92% compared to the control). The obtained data show that a significant phytotoxic effect is observed by all biometric indices of Triticum aestivum in all studied variants. The highest phytotoxic effect (33.56–42.70%) was observed in variants with combined contamination (PP+Zn+Pb). The results of probiotic application show a phytotoxic effect of less than 20% by all biometric indices of Triticum aestivum for all studied variants. Therefore, the results of the research can be used to develop recommendations for the remediation of land contaminated by military actions in Ukraine and the creation of sustainable agroecosystems.
Wydawca
Rocznik
Tom
Strony
94--99
Opis fizyczny
Bilbiogr. 22 poz., tab.
Twórcy
autor
- Poltava State Agrarian University, Skovorody St., 1/3, Poltava, 36003, Ukraine
autor
- Poltava State Agrarian University, Skovorody St., 1/3, Poltava, 36003, Ukraine
autor
- Poltava State Agrarian University, Skovorody St., 1/3, Poltava, 36003, Ukraine
autor
- Uman National University of Horticulture, 1 Instytutska St., Uman, 20305, Ukraine
autor
- Poltava State Agrarian University, Skovorody St., 1/3, Poltava, 36003, Ukraine
autor
- Poltava State Agrarian University, Skovorody St., 1/3, Poltava, 36003, Ukraine
Bibliografia
- 1. Baldi F., Leonardi V., D’Annibale A., Piccolo A., Zecchini F., Petruccioli M. 2007. Integrated approach of metal removal and bioprecipitation followed by fungal degradation of organic pollutants from contaminated soils. European Journal of Soil Biology, 43(5–6), 380–387. doi.org/10.1016/j.ejsobi.2007.03.013
- 2. Cui Zh., Zhang Xu, Yang Hu., Sun Li. 2017. Bioremediation of heavy metal pollution utilizing composite microbial agent of Mucor circinelloides, Actinomucor sp. and Mortierella sp. Journal of Environmental Chemical Engineering, 5(4), 3616–3621. doi.org/10.1016/j.jece.2017.07.021
- 3. Devi A., Fernando L., Ferreira R., Saratale G.D., Mulla S.I., More N., Bharagava R.N. 2022. Chapter1 - Microbe-assisted phytoremediation of environmental contaminants, Editor(s): Kuldeep Bauddh, Ying Ma. Advances in Microbe-assisted Phytoremediation of Polluted Sites, Elsevier, 3–26. doi.org/10.1016/B978-0-12-823443-3.00001-6
- 4. DSTU 4770.9:2007 Soil quality. Determination of the content of mobile Pb compounds in the soil in a buffered ammonium-acetate extract with pH 4.8 by the method of atomic absorption spectrophotometry. (in Ukrainian)
- 5. DSTU 4770.2:2007 Soil quality. Determination of the content of mobile Zn compounds in the soil in a buffer ammonium acetate extract with pH 4.8 by the method of atomic absorption spectrophotometry. (in Ukrainian)
- 6. Guo H., Luo Sh., Chen Li., Xiao Xi., Xi Qia., Wei W., Zeng G., Liu Ch., Wan Yo., Chen Jue., He Ye. 2010. Bioremediation of heavy metals by growing hyperaccumulaor endophytic bacterium Bacillus sp. L14. Bioresource Technology, 101(22), 8599–8605. doi.org/10.1016/j.biortech.2010.06.085
- 7. Hrytsaienko H.M. 2003. Metody biolohichnykh ta ahrokhimichnykh doslidzhen roslyn i gruntiv. Kyiv, 320 p. (in Ukrainian)
- 8. ISO 11269-2: 2002 Soil quality -- Determination of the effects of pollutants on soil flora - Part 2: Effects of chemicals on the emergence and growth of higher plants.
- 9. ISO 11269-1:2004. Soil quality -- Determination of the effects of pollutants on soil flora - Part 1: Method for the measurement of inhibition of root.
- 10. Mo A., Li H., Zhai Y., Yang H., Wang J., Wang Y., Yi L., Guo W., Yuan Y. 2022. Assessment of Bacillus subtilis applied in rice-crayfish coculture system on physicochemical properties, microbial sulfur cycling, Cd accumulation and bioavailability. Journal of Cleaner Production, 381(1), 135158, doi.org/10.1016/j.jclepro.2022.135158.
- 11. МVV 31-497058-009-2002 Soils. Determination of the mass fraction of petroleum products in the soil by infrared spectroscopy. (in Ukrainian)
- 12. Patyka, V.P., Taranenko, S.V., Taranenko, A.O., Kalinichenko, A.V. 2014. Microbial biom of different soils and soil-climatic zones of Poltava region. Mikrobiolohichnyĭ zhurnal, 76(5), 20–25.
- 13. Pysarenko, P.V., Korchahin, O.P. 2020. Ecological substantiation of water eutrophication processes regulation. Tavriiskyi visnyk, 14, 274–283.
- 14. Pysarenko, P., Samoilik, M., Taranenko, A., Tsova, Y., Sereda, M. 2021a. Influence of probiotics-based products on phytopathogenic bacteria and fungi in agrocenosis. Agraarteadus, 32(2), 303–306. doi.org/10.15159/jas.21.41a
- 15. Pysarenko, P.V., Samoilik, M.S., Dychenko, O.Yu., Sereda, M.S., Korchahin, О.Р. 2021b. Improving eutrophication regulation of water bodies by using biological methods. Bulletin of Poltava State Agrarian Academy, (2), 135–144. doi.org/10.31210/visnyk2021.02.16
- 16. Pysarenko, P.V., Samoilik, M.S., Taranenko A., Tsova Y.I, Sereda М.S. 2021c. Bioremediation of contaminated soil with petroleum products. Agriculture and forestry: Scientific journals of Vinnitsa National Agrarian University, 3(22), 145–160
- 17. Pysarenko P., Samoilik M., Taranenko A., Tsova Y., Taranenko S. 2022a. Microbial remediation of petroleum polluted soil. Agraarteadus, 2(33), 434–442. doi.org/10.15159/jas.22.30
- 18. Pysarenko P., Samojlik M., Taranenko A., Tsova Yu.i, Horobets M., Filonenko S. 2022b. Monitoring of Municipal Solid Waste Landfill Impact on Environment in Poltava Region, Ukraine. Ecological Engineering and Environmental Technology, 5, 54–60. doi.org/10.12912/27197050/151630
- 19. Status of the World’s Soil Resources (SWSR) – Main Report. FAO and ITPS. 2015. Food and Agriculture Organization of the United Nations and Intergovernmental Technical Panel on Soils, Rome, Italy.
- 20. Vasyliuk O., Shyriaieva D., Kolomytsev G., Spinova J. 2017. Steppe protected areas on the territory of Ukraine in the context of the armed conflict in the Donbas region and Russian annexation of the Crimean Peninsula. Bulletin of the Eurasian Dry Grassland Group, 1(33), 15–23. (in Ukrainian)
- 21. Xu T., Xi J., Ke J., Wang Yu., Chen Xi., Zhang Z., Lin Y. 2023. Deciphering soil amendments and actinomycetes for remediation of cadmium (Cd) contaminated farmland, Toxicology and Environmental Safety, 249, 114388. doi.org/10.1016/j.ecoenv.2022.114388
- 22. Zhao D., Cheah W.Y., Lai S.H., Ng E.-P., Khoo K.S., Show P.L., Chuan L.T. 2023. Symbiosis of microalgae and bacteria consortium for heavy metal remediation in wastewater. Journal of Environmental Chemical Engineering, 11(3), 109943. doi.org/10.1016/j.jece.2023.109943
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-87bd58ff-be81-4804-8f10-1f00f3ccaf22