Assessment of The Use of Artemisia Dracunculus L and Erigeron Canadensis in The Remediation of Heavy Metal Contaminated Soils and Their Ability to Phytoextraction and Biomass Yield.
Year 2022,
Volume: 11 Issue: 4, 1 - 10, 28.12.2022
Ayhan Kocaman
Abstract
Different hyperaccumulator plants growing in the same contaminated soil may have excessive accumulation of different metals or produce biomass. Therefore, it is important to determine the ability of the plant to improve the soil under natural conditions in the improvement of heavy metal-contaminated lands with hyperaccumulator plants. This study focused on the phytoremediation and biomass production capabilities of Artemisa Dracunculus L. and Erigeron Canadensis plants. Considering this fact, Erigeron Canadensis was determined to have the highest phytoextraction potential between the two plants, as it produces more biomass (96%) and mineral content (169%) than Artemisa Dracunculus L. This shows that Erigeron Canadensis has more phytoremediation potential than Artemisa Dracunculus L. and that Erigeron Canadensis plant is one of the alternative hyperaccumulator plant candidates and is more effective for soil reclamation. In addition, when the plants were categorized according to their BAF values, accumulator (1
Supporting Institution
“Karabuk University Scientific Research Center (BAP).
Project Number
grant number FOA-2020-2280.”
Thanks
I would like to thank my supervisor Prof. Metin Turan for his consistent support and guidance during the running of this project. Furthermore, I would also like to acknowledge the Karabuk University Scientific Research Center (BAP) for their participation and engagement in the study.
References
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- 7 Hasan M, Uddin M, Ara-Sharmeen I, F Alharby H, Alzahrani Y, Hakeem KR, et al. Assisting phytoremediation of heavy metals using chemical amendments. Plants. 2019;8(9):295.
- 8 Khalid S, Shahid M, Niazi NK, Murtaza B, Bibi I, Dumat C. A comparison of technologies for remediation of heavy metal contaminated soils. Journal of Geochemical Exploration. 2017;182:247-68.
- 9 Xin J, Ma S, Li Y, Zhao C, Tian R. Pontederia cordata, an ornamental aquatic macrophyte with great potential in phytoremediation of heavy-metal-contaminated wetlands. Ecotoxicology and Environmental Safety. 2020;203:111024.
- 10 Salas-Moreno M, Marrugo-Negrete J. Phytoremediation potential of Cd and Pb-contaminated soils by Paspalum fasciculatum Willd. ex Flüggé. International Journal of Phytoremediation. 2020;22(1):87-97.
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- 12 Kaur L. Role of Phytoremediation Strategies in Removal of Heavy Metals. Emerging Issues in the Water Environment during Anthropocene. 2020:223-59.
- 13 Verbruggen N, Hermans C, Schat H. Molecular mechanisms of metal hyperaccumulation in plants. New phytologist. 2009;181(4):759-76.
- 14 Wang J, Xiong Y, Zhang J, Lu X, Wei G. Naturally selected dominant weeds as heavy metal accumulators and excluders assisted by rhizosphere bacteria in a mining area. Chemosphere. 2020;243:125365.
- 15 Mertens D. AOAC official method 922.02. Plants preparation of laboratuary sample. Official Methods of Analysis. Chapter. 2005;3:20877-2417.
- 16 Koppejan J, Van Loo S. The handbook of biomass combustion and co-firing: Routledge; 2012.
- 17Houzelot V, Laubie B, Pontvianne S, Simonnot M-O. Effect of up-scaling on the quality of ashes obtained from hyperaccumulator biomass to recover Ni by agromining. Chemical Engineering Research and Design. 2017;120:26-33.
- 18 Cassayre L, Hazotte C, Laubie B, Carvalho Jr W, Simonnot M-O. Combustion of nickel hyperaccumulator plants investigated by experimental and thermodynamic approaches. Chemical Engineering Research and Design. 2020;160:162-74.
- 19 Lin H, Liu J, Dong Y, He Y. The effect of substrates on the removal of low-level vanadium, chromium and cadmium from polluted river water by ecological floating beds. Ecotoxicology and Environmental Safety. 2019;169:856-62.
- 20 Qian Y, Gallagher FJ, Feng H, Wu M, Zhu Q. Vanadium uptake and translocation in dominant plant species on an urban coastal brownfield site. Science of the Total Environment. 2014;476:696-704.
- 21 Liu J-g, Qu P, Zhang W, Dong Y, Li L, Wang M-x. Variations among rice cultivars in subcellular distribution of Cd: the relationship between translocation and grain accumulation. Environmental and experimental botany. 2014;107:25-31.
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- 24 Ma LQ, Komar KM, Tu C, Zhang W, Cai Y, Kennelley ED. A fern that hyperaccumulates arsenic. Nature. 2001;409(6820):579-.
- 25 Yang X, Li T, Yang J, He Z, Lu L, Meng F. Zinc compartmentation in root, transport into xylem, and absorption into leaf cells in the hyperaccumulating species of Sedum alfredii Hance. Planta. 2006;224(1):185-95.
- 26 Baker AJ. Accumulators and excluders‐strategies in the response of plants to heavy metals. Journal of plant nutrition. 1981;3(1-4):643-54.
- 27 Harikumar P, Nasir U, Rahman M. Distribution of heavy metals in the core sediments of a tropical wetland system. International Journal of Environmental Science & Technology. 2009;6(2):225-32.
- 28 Inengite A, Abasi C, Walter C. Application of pollution indices for the assessment of heavy metal pollution in flood impacted soil. International research journal of pure & applied chemistry. 2015;8(3):175-89.
- 29 Tomlinson D, Wilson J, Harris C, Jeffrey D. Problems in the assessment of heavy-metal levels in estuaries and the formation of a pollution index. Helgoländer meeresuntersuchungen. 1980;33(1):566-75.
- 30 Yang Z, Lu W, Long Y, Bao X, Yang Q. Assessment of heavy metals contamination in urban topsoil from Changchun City, China. Journal of Geochemical Exploration. 2011;108(1):27-38.
- 31Franco-Uría A, López-Mateo C, Roca E, Fernández-Marcos ML. Source identification of heavy metals in pastureland by multivariate analysis in NW Spain. Journal of hazardous materials. 2009;165(1-3):1008-15.
- 32 Zheng L, Zhou Z, Rao M, Sun Z. Assessment of heavy metals and arsenic pollution in surface sediments from rivers around a uranium mining area in East China. Environmental Geochemistry and Health. 2020;42(5):1401-13.
- 33 Proshad R, Kormoker T, Islam S. Distribution, source identification, ecological and health risks of heavy metals in surface sediments of the Rupsa River, Bangladesh. Toxin reviews. 2019.
- 34 Zhao F, Lombi E, McGrath S. Assessing the potential for zinc and cadmium phytoremediation with the hyperaccumulator Thlaspi caerulescens. Plant and soil. 2003;249(1):37-43.
- 35 Wang L, Dai L, Li L, Liang T. Multivariable cokriging prediction and source analysis of potentially toxic elements (Cr, Cu, Cd, Pb, and Zn) in surface sediments from Dongting Lake, China. Ecological Indicators. 2018;94:312-9.
- 36 Wang X, Fu R, Li H, Zhang Y, Lu M, Xiao K, et al. Heavy metal contamination in surface sediments: A comprehensive, large-scale evaluation for the Bohai Sea, China. Environmental Pollution. 2020;260:113986.
- 37 Alaboudi KA, Ahmed B, Brodie G. Phytoremediation of Pb and Cd contaminated soils by using sunflower (Helianthus annuus) plant. Annals of agricultural sciences. 2018;63(1):123-7.
- 38 Tang H, Li T, Yu H, Zhang X. Cadmium accumulation characteristics and removal potentials of high cadmium accumulating rice line grown in cadmium-contaminated soils. Environmental Science and Pollution Research. 2016;23(15):15351-7.
- 39 Ghasemidehkordi B, Malekirad AA, Nazem H, Fazilati M, Salavati H, Shariatifar N, et al. Concentration of lead and mercury in collected vegetables and herbs from Markazi province, Iran: a non-carcinogenic risk assessment. Food and chemical toxicology. 2018;113:204-10.
- 40 Golubkina N, Shevchuk O, Logvinenko L, Molchanova A, Plugatar YV, editors. Macro and trace element accumulation by species of genus Artemisia on the southern coast of the Crimea. VIII International Scientific and Practical Conference on Biotechnology as an Instrument for Plant Biodiversity Conservation 1324; 2018.
- 41 Ozyigit II, Yalcin B, Turan S, Saracoglu IA, Karadeniz S, Yalcin IE, et al. Investigation of heavy metal level and mineral nutrient status in widely used medicinal plants’ leaves in Turkey: Insights into health implications. Biological trace element research. 2018;182(2):387-406.
- 42 Yu S, Sheng L, Mao H, Huang X, Luo L, Li Y. Physiological response of Conyza Canadensis to cadmium stress monitored by Fourier transform infrared spectroscopy and cadmium accumulation. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy. 2020;229:118007.
- 43 Xia H, Liang D, Chen F, Liao Ma, Lin L, Tang Y, et al. Effects of mutual intercropping on cadmium accumulation by the accumulator plants Conyza canadensis, Cardamine hirsuta, and Cerastium glomeratum. International journal of phytoremediation. 2018;20(9):855-61.
- 44 Zhuang P, Ye Z, Lan C, Xie Z, Shu W. Chemically assisted phytoextraction of heavy metal contaminated soils using three plant species. Plant and Soil. 2005;276(1):153-62.
- 45 Lombi E, Zhao F, Dunham S, McGrath S. Phytoremediation of heavy metal–contaminated soils: Natural hyperaccumulation versus chemically enhanced phytoextraction. Journal of Environmental Quality. 2001;30(6):1919-26.
- 46 Koul B, Yakoob M, Shah MP. Agricultural waste management strategies for environmental sustainability. Environmental Research. 2022;206:112285.
Year 2022,
Volume: 11 Issue: 4, 1 - 10, 28.12.2022
Ayhan Kocaman
Project Number
grant number FOA-2020-2280.”
References
- 1. Cozma P, Hlihor R-M, Roșca M, Minuț M, Diaconu M, Gavrilescu M, editors. Coupling Phytoremediation with Plant Biomass Valorisation and Metal Recovery: an Overview. 2021 International Conference on e-Health and Bioengineering (EHB); 2021: IEEE.
- 2. ÖZKUTLU F, KARA ŞM. Cd concentration of durum wheat grain as influenced by soil salinity. Akademik Ziraat Dergisi. 2019;8(1):97-100.
- 3. Zhou B, Zhao L, Sun Y, Li X, Weng L, Li Y. Contamination and human health risks of phthalate esters in vegetable and crop soils from the Huang-Huai-Hai region of China. Science of the Total Environment. 2021;778:146281.
- 4 Lv G, Yang T, Chen Y, Hou H, Liu X, Li J, et al. Biochar-based fertilizer enhanced Cd immobilization and soil quality in soil-rice system. Ecological Engineering. 2021;171:106396.
- 5 Suman J, Uhlik O, Viktorova J, Macek T. Phytoextraction of heavy metals: a promising tool for clean-up of polluted environment? Frontiers in plant science. 2018:1476.
- 6 Murray EW, Greenberg BM, Cryer K, Poltorak B, McKeown J, Spies J, et al. Kinetics of phytoremediation of petroleum hydrocarbon contaminated soil. International journal of phytoremediation. 2019;21(1):27-33.
- 7 Hasan M, Uddin M, Ara-Sharmeen I, F Alharby H, Alzahrani Y, Hakeem KR, et al. Assisting phytoremediation of heavy metals using chemical amendments. Plants. 2019;8(9):295.
- 8 Khalid S, Shahid M, Niazi NK, Murtaza B, Bibi I, Dumat C. A comparison of technologies for remediation of heavy metal contaminated soils. Journal of Geochemical Exploration. 2017;182:247-68.
- 9 Xin J, Ma S, Li Y, Zhao C, Tian R. Pontederia cordata, an ornamental aquatic macrophyte with great potential in phytoremediation of heavy-metal-contaminated wetlands. Ecotoxicology and Environmental Safety. 2020;203:111024.
- 10 Salas-Moreno M, Marrugo-Negrete J. Phytoremediation potential of Cd and Pb-contaminated soils by Paspalum fasciculatum Willd. ex Flüggé. International Journal of Phytoremediation. 2020;22(1):87-97.
- 11 Liu L, Li W, Song W, Guo M. Remediation techniques for heavy metal-contaminated soils: Principles and applicability. Science of the Total Environment. 2018;633:206-19.
- 12 Kaur L. Role of Phytoremediation Strategies in Removal of Heavy Metals. Emerging Issues in the Water Environment during Anthropocene. 2020:223-59.
- 13 Verbruggen N, Hermans C, Schat H. Molecular mechanisms of metal hyperaccumulation in plants. New phytologist. 2009;181(4):759-76.
- 14 Wang J, Xiong Y, Zhang J, Lu X, Wei G. Naturally selected dominant weeds as heavy metal accumulators and excluders assisted by rhizosphere bacteria in a mining area. Chemosphere. 2020;243:125365.
- 15 Mertens D. AOAC official method 922.02. Plants preparation of laboratuary sample. Official Methods of Analysis. Chapter. 2005;3:20877-2417.
- 16 Koppejan J, Van Loo S. The handbook of biomass combustion and co-firing: Routledge; 2012.
- 17Houzelot V, Laubie B, Pontvianne S, Simonnot M-O. Effect of up-scaling on the quality of ashes obtained from hyperaccumulator biomass to recover Ni by agromining. Chemical Engineering Research and Design. 2017;120:26-33.
- 18 Cassayre L, Hazotte C, Laubie B, Carvalho Jr W, Simonnot M-O. Combustion of nickel hyperaccumulator plants investigated by experimental and thermodynamic approaches. Chemical Engineering Research and Design. 2020;160:162-74.
- 19 Lin H, Liu J, Dong Y, He Y. The effect of substrates on the removal of low-level vanadium, chromium and cadmium from polluted river water by ecological floating beds. Ecotoxicology and Environmental Safety. 2019;169:856-62.
- 20 Qian Y, Gallagher FJ, Feng H, Wu M, Zhu Q. Vanadium uptake and translocation in dominant plant species on an urban coastal brownfield site. Science of the Total Environment. 2014;476:696-704.
- 21 Liu J-g, Qu P, Zhang W, Dong Y, Li L, Wang M-x. Variations among rice cultivars in subcellular distribution of Cd: the relationship between translocation and grain accumulation. Environmental and experimental botany. 2014;107:25-31.
- 22 Baker AJ, Brooks R. Terrestrial higher plants which hyperaccumulate metallic elements. A review of their distribution, ecology and phytochemistry. Biorecovery. 1989;1(2):81-126.
- 23 Deram A, Denayer F-O, Petit D, Van Haluwyn C. Seasonal variations of cadmium and zinc in Arrhenatherum elatius, a perennial grass species from highly contaminated soils. Environmental Pollution. 2006;140(1):62-70.
- 24 Ma LQ, Komar KM, Tu C, Zhang W, Cai Y, Kennelley ED. A fern that hyperaccumulates arsenic. Nature. 2001;409(6820):579-.
- 25 Yang X, Li T, Yang J, He Z, Lu L, Meng F. Zinc compartmentation in root, transport into xylem, and absorption into leaf cells in the hyperaccumulating species of Sedum alfredii Hance. Planta. 2006;224(1):185-95.
- 26 Baker AJ. Accumulators and excluders‐strategies in the response of plants to heavy metals. Journal of plant nutrition. 1981;3(1-4):643-54.
- 27 Harikumar P, Nasir U, Rahman M. Distribution of heavy metals in the core sediments of a tropical wetland system. International Journal of Environmental Science & Technology. 2009;6(2):225-32.
- 28 Inengite A, Abasi C, Walter C. Application of pollution indices for the assessment of heavy metal pollution in flood impacted soil. International research journal of pure & applied chemistry. 2015;8(3):175-89.
- 29 Tomlinson D, Wilson J, Harris C, Jeffrey D. Problems in the assessment of heavy-metal levels in estuaries and the formation of a pollution index. Helgoländer meeresuntersuchungen. 1980;33(1):566-75.
- 30 Yang Z, Lu W, Long Y, Bao X, Yang Q. Assessment of heavy metals contamination in urban topsoil from Changchun City, China. Journal of Geochemical Exploration. 2011;108(1):27-38.
- 31Franco-Uría A, López-Mateo C, Roca E, Fernández-Marcos ML. Source identification of heavy metals in pastureland by multivariate analysis in NW Spain. Journal of hazardous materials. 2009;165(1-3):1008-15.
- 32 Zheng L, Zhou Z, Rao M, Sun Z. Assessment of heavy metals and arsenic pollution in surface sediments from rivers around a uranium mining area in East China. Environmental Geochemistry and Health. 2020;42(5):1401-13.
- 33 Proshad R, Kormoker T, Islam S. Distribution, source identification, ecological and health risks of heavy metals in surface sediments of the Rupsa River, Bangladesh. Toxin reviews. 2019.
- 34 Zhao F, Lombi E, McGrath S. Assessing the potential for zinc and cadmium phytoremediation with the hyperaccumulator Thlaspi caerulescens. Plant and soil. 2003;249(1):37-43.
- 35 Wang L, Dai L, Li L, Liang T. Multivariable cokriging prediction and source analysis of potentially toxic elements (Cr, Cu, Cd, Pb, and Zn) in surface sediments from Dongting Lake, China. Ecological Indicators. 2018;94:312-9.
- 36 Wang X, Fu R, Li H, Zhang Y, Lu M, Xiao K, et al. Heavy metal contamination in surface sediments: A comprehensive, large-scale evaluation for the Bohai Sea, China. Environmental Pollution. 2020;260:113986.
- 37 Alaboudi KA, Ahmed B, Brodie G. Phytoremediation of Pb and Cd contaminated soils by using sunflower (Helianthus annuus) plant. Annals of agricultural sciences. 2018;63(1):123-7.
- 38 Tang H, Li T, Yu H, Zhang X. Cadmium accumulation characteristics and removal potentials of high cadmium accumulating rice line grown in cadmium-contaminated soils. Environmental Science and Pollution Research. 2016;23(15):15351-7.
- 39 Ghasemidehkordi B, Malekirad AA, Nazem H, Fazilati M, Salavati H, Shariatifar N, et al. Concentration of lead and mercury in collected vegetables and herbs from Markazi province, Iran: a non-carcinogenic risk assessment. Food and chemical toxicology. 2018;113:204-10.
- 40 Golubkina N, Shevchuk O, Logvinenko L, Molchanova A, Plugatar YV, editors. Macro and trace element accumulation by species of genus Artemisia on the southern coast of the Crimea. VIII International Scientific and Practical Conference on Biotechnology as an Instrument for Plant Biodiversity Conservation 1324; 2018.
- 41 Ozyigit II, Yalcin B, Turan S, Saracoglu IA, Karadeniz S, Yalcin IE, et al. Investigation of heavy metal level and mineral nutrient status in widely used medicinal plants’ leaves in Turkey: Insights into health implications. Biological trace element research. 2018;182(2):387-406.
- 42 Yu S, Sheng L, Mao H, Huang X, Luo L, Li Y. Physiological response of Conyza Canadensis to cadmium stress monitored by Fourier transform infrared spectroscopy and cadmium accumulation. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy. 2020;229:118007.
- 43 Xia H, Liang D, Chen F, Liao Ma, Lin L, Tang Y, et al. Effects of mutual intercropping on cadmium accumulation by the accumulator plants Conyza canadensis, Cardamine hirsuta, and Cerastium glomeratum. International journal of phytoremediation. 2018;20(9):855-61.
- 44 Zhuang P, Ye Z, Lan C, Xie Z, Shu W. Chemically assisted phytoextraction of heavy metal contaminated soils using three plant species. Plant and Soil. 2005;276(1):153-62.
- 45 Lombi E, Zhao F, Dunham S, McGrath S. Phytoremediation of heavy metal–contaminated soils: Natural hyperaccumulation versus chemically enhanced phytoextraction. Journal of Environmental Quality. 2001;30(6):1919-26.
- 46 Koul B, Yakoob M, Shah MP. Agricultural waste management strategies for environmental sustainability. Environmental Research. 2022;206:112285.