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Communications in Soil Science and Plant Analysis Volume 40, 2009 - Issue 19-20
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Original Articles

Amaranthus Tricolor Has the Potential for Phytoremediation of Cadmium‐Contaminated Soils

Toshihiro Watanabe Research Faculty of Agriculture, Hokkaido University, Hokkaido, JapanCorrespondence[email protected]
,
Yasutoshi Murata Research Faculty of Agriculture, Hokkaido University, Hokkaido, Japan
&
Mitsuru Osaki Research Faculty of Agriculture, Hokkaido University, Hokkaido, Japan
Pages 3158-3169 | Received 17 Jan 2008, Accepted 12 Mar 2009, Published online: 27 Oct 2009

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J. O. Azeez, T. B. Olowoboko, B. S. Bada, J. N. Odedina & O. O. Onasanya. (2020) Evaluation of soil metal sorption characteristics and heavy metal extractive ability of indigenous plant species in Abeokuta, Nigeria. International Journal of Phytoremediation 22:8, pages 872-884.
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Raymond Ahulle Wuana & Phoebe Ahemen Mbasugh. (2013) Response of roselle (Hibiscus sabdariffa) to heavy metals contamination in soils with different organic fertilisations. Chemistry and Ecology 29:5, pages 437-447.
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Articles from other publishers (22)

Zakane Reshma & Kowshik Meenal. (2024) Zinc biofortification and implications on growth, nutrient efficiency, and stress response in Amaranthus cruentus through soil application of biosynthesized nanoparticles. Applied Food Research 4:1, pages 100385.
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Chengming Zhang, Chaoqun Zhang, Takayuki Azuma, Hayato Maruyama, Takuro Shinano & Toshihiro Watanabe. (2023) Different nitrogen acquirement and utilization strategies might determine the ecological competition between ferns and angiosperms. Annals of Botany 131:7, pages 1097-1106.
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Roghieh Hajiboland, Aiuob Moradi, Ehsan Kahneh, Charlotte Poschenrieder, Fatemeh Nazari, Jelena Pavlovic, Roser Tolra, Seyed-Yahya Salehi-Lisar & Miroslav Nikolic. (2023) Weed Species from Tea Gardens as a Source of Novel Aluminum Hyperaccumulators. Plants 12:11, pages 2129.
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Cristina Hegedus, Simona-Nicoleta Pașcalău, Luisa Andronie, Ancuţa-Simona Rotaru, Alexandra-Antonia Cucu & Daniel Severus Dezmirean. (2023) The Journey of 1000 Leagues towards the Decontamination of the Soil from Heavy Metals and the Impact on the Soil–Plant–Animal–Human Chain Begins with the First Step: Phytostabilization/Phytoextraction. Agriculture 13:3, pages 735.
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Fatemeh Nazari, Roghieh Hajiboland, Seyed-Yahya Salehi-Lisar, Ehsan Kahneh, Aioub Moradi & Charlotte Poschenrieder. (2023) Aluminum accumulation in Amaranthus species and mechanisms of Al tolerance. Biologia 78:8, pages 2029-2047.
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Xuening Cheng, Can Chen, Yuming Hu, Xiliang Guo & Jianlong Wang. (2022) Photosynthesis and growth of Amaranthus tricolor under strontium stress. Chemosphere 308, pages 136234.
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Jadwiga Wyszkowska, Edyta Boros-Lajszner, Agata Borowik & Jan Kucharski. (2022) The Role of Cellulose in Microbial Diversity Changes in the Soil Contaminated with Cadmium. Sustainability 14:21, pages 14242.
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Salwinder Singh Dhaliwal, Vivek Sharma, Janpriya Kaur, Arvind Kumar Shukla, Jaswinder Singh & Prabhjot Singh. (2022) Cadmium phytoremediation potential of Brassica genotypes grown in Cd spiked Loamy sand soils: Accumulation and tolerance. Chemosphere 302, pages 134842.
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Fatemeh Baniasadi, Masoud Arghavani, Vahid Reza Saffari & Mehdi Mansouri. (2022) Multivariate analysis of morpho-physiological traits in Amaranthus tricolor as affected by nitric oxide and cadmium stress. Environmental Science and Pollution Research 29:32, pages 49092-49104.
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Svetlana V. Gorelova, Murat S. Gins & Marina V. Frontasyeva. (2022) Phytoextraction of toxic elements by Amaranthus Tricolor grown on technogenically polluted soils in open ground conditions . Chimica Techno Acta 9:2S.
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Salwinder Singh Dhaliwal, Vivek Sharma, Parminder Kaur Taneja, Arvind Kumar Shukla, Lovedeep Kaur, Gayatri Verma, Vibha Verma & Jagdish Singh. (2021) Effect of cadmium and ethylenediamine tetraacetic acid supplementation on cadmium accumulation by roots of Brassica species in Cd spiked soil. Environmental Science and Pollution Research 29:4, pages 6000-6009.
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Mahrous Awad, M. A. El-Desoky, A. Ghallab, Jan Kubes, S. E. Abdel-Mawly, Subhan Danish, Disna Ratnasekera, Mohammad Sohidul Islam, Milan Skalicky, Marian Brestic, Alaa Baazeem, Saqer S. Alotaibi, Talha Javed, Rubab Shabbir, Shah Fahad, Muhammad Habib ur Rahman & Ayman EL Sabagh. (2021) Ornamental Plant Efficiency for Heavy Metals Phytoextraction from Contaminated Soils Amended with Organic Materials. Molecules 26:11, pages 3360.
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Weiqin Xing, Hui Liu, Travis Banet, Hongsheng Wang, James A. Ippolito & Liping Li. (2020) Cadmium, copper, lead and zinc accumulation in wild plant species near a lead smelter. Ecotoxicology and Environmental Safety 198, pages 110683.
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Henrik Haller, Anders Jonsson, Martha Lacayo Romero & Martha Jarquín Pascua. (2018) Bioaccumulation and translocation of field-weathered toxaphene and other persistent organic pollutants in three cultivars of amaranth (A. cruentus ‘R127 México’, A. cruentus ‘Don León’ y A. caudatus ‘CAC 48 Perú’) – A field study from former cotton fields in Chinandega, Nicaragua. Ecological Engineering 121, pages 65-71.
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N. G. Osmolovskaya, Vu Viet Dung, Z. K. Kudryashova, L. N. Kuchaeva & N. F. Popova. (2018) Effect of Cadmium on Distribution of Potassium, Calcium, Magnesium, and Oxalate Accumulation in Amaranthus cruentus L. Plants. Russian Journal of Plant Physiology 65:4, pages 553-562.
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Н. Г. ОсмоловскаяВьет Зунг ВуЗ. К. КудряшеваЛ. Н. КунаеваН.Ф. Попова. (2018) ВЛИЯНИЕ КАДМИЯ НА РАСПРЕДЕЛЕНИЕ КАЛИЯ, КАЛЬЦИЯ, МАГНИЯ И АККУМУЛЯЦИЮ ОКСАЛАТА В РАСТЕНИЯХ AMARANTHUS CRUENTUS L., "Физиология растений". Физиология растений:4, pages 301-309.
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Rezwana Assad, Zafar A. Reshi, Snober Jan & Irfan Rashid. (2017) Biology of Amaranths. The Botanical Review 83:4, pages 382-436.
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Jingtao Wu, Camille Dumat, Huanping Lu, Yingwen Li, Hanqing Li, Yanhui Xiao, Ping Zhuang & Zhian Li. (2015) Synergistic improvement of crop physiological status by combination of cadmium immobilization and micronutrient fertilization. Environmental Science and Pollution Research 23:7, pages 6661-6670.
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Huanping Lu, Zhian Li, Shenglei Fu, Ana Méndez, Gabriel Gascó & Jorge Paz-Ferreiro. (2014) Can Biochar and Phytoextractors Be Jointly Used for Cadmium Remediation?. PLoS ONE 9:4, pages e95218.
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M. Devi Chinmayee, B. Mahesh, S. Pradesh, I. Mini & T. S. Swapna. (2012) The Assessment of Phytoremediation Potential of Invasive Weed Amaranthus spinosus L.. Applied Biochemistry and Biotechnology 167:6, pages 1550-1559.
Crossref
Ackmez Mudhoo. 2011. Green Chemistry for Environmental Remediation. Green Chemistry for Environmental Remediation 661 698 .
Xuening Cheng, Can Chen, Yuming Hu & Jianlong Wang. (2022) Photosynthesis and Growth of Amaranthus Tricolor Under Strontium Stress. SSRN Electronic Journal.
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