Research Article
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Year 2022, , 184 - 197, 01.07.2022
https://doi.org/10.18393/ejss.1057928

Abstract

References

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  • De Steur, H., Gellynck, X., Blancquaert, D., Lambert, W., Van Der Straeten, D., Qaim, M., 2012. Potential impact and cost-effectiveness of multi-biofortified rice in China. New Biotechnology 29(3): 432-442.
  • Doabi, S.A., Karami, M., Afyuni, M., Yeganeh, M., 2018. Pollution and health risk assessment of heavy metals in agricultural soil, atmospheric dust and major food crops in Kermanshah province, Iran. Ecotoxicology and Environmental Safety 163: 153-164.
  • Erenoglu, E.B., Kutman, U.B., Ceylan, Y., Yildiz, B., Cakmak, I., 2011. Improved nitrogen nutrition enhances root uptake, root‐to‐shoot translocation and remobilization of zinc (65Zn) in wheat. New Phytologist 189(2): 438-448.
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  • Gohil, N.B., Patel, D.P., Patel, B.A., Pathan, O.I., 2017. Effect of soil application of Fe and Zn on nutrient content and uptake by two rice varieties. International Journal of Chemical Studies 5(2): 396-400.
  • Gupta, N., Ram, H. and Kumar, B., 2016. Mechanism of Zinc absorption in plants: uptake, transport, translocation and accumulation. Reviews in Environmental Science and Bio/Technology 15(1): 89-109.
  • Hafeez, B.M.K.Y., Khanif, Y.M., Saleem, M., 2013. Role of zinc in plant nutrition-a review. Journal of Experimental Agriculture International 3(2): 374-391.
  • Hotz, C., Brown, K.H., 2004. Assessment of the risk of zinc deficiency in populations and options for its control. Available at [Access date: 28.10.2021]: https://archive.unu.edu/unupress/food/fnb25-1s-IZiNCG.pdf
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Biogeoaccumulation of zinc in hybrid rice (Oryza sativa L.) in an Inceptisol amended with soil zinc application and its bioavailability to human being

Year 2022, , 184 - 197, 01.07.2022
https://doi.org/10.18393/ejss.1057928

Abstract

Soil Zn amended is an efficient agronomical Zn biofortification approach in rice. However, it is still need to know if higher rate of Zn over recommended dose can influence other essential nutrient uptake, high accumulation of Zn in soils and health risk for human consumption. This study was conducted by taking ten treatments (T1: control, T2: RDF, T3: RDF + 1.25 mg kg-1, T4: RDF + 2.5 mg kg-1, T5: RDF + 3.75 mg kg-1, T6: RDF + 5 mg kg-1, T7: RDF + 6.25 mg kg-1, T8: RDF + 7.5 mg kg-1, T9: RDF + 8.75 mg kg-1, T10: RDF + 10 mg kg-1) on hybrid rice in Zn (1.20 mg kg-1) enriched soil. The findings have shown that 6.25 mg kg-1 Zn application significantly increased crop growth and grain concentrations of N, K, Zn, Cu and Fe by 71.4, 125, 78.9, 28.5 and 2.4%, respectively. Nutrient harvest index was significantly affected by ranged between 29.1–36.4%. Application of Zn at 6.25 mg kg-1 (T7) recorded the highest Zn concentration in grain (28.2 mg kg-1) and bioavailability of the fortified Zn (2.05 mg Zn day-1). The lowest phytatic acid concentration in grain was recorded in T8 (RDF + Zn at 7.5 mg kg-1) and after that a significant increase was observed. Transfer coefficient was inversely behaving with Zn application and ranged between 6.03–18.0 grain. The average daily intake of Zn was ranged between 0.075–0.118 mg-1 kg-1 day. Across different treatments the Zn build-up factor, geo-accumulation index and soil enrichment factor was ranged between 0.98–4.90, -0.61–1.70 and 0.24–1.82, respectively in post-harvest soil. In conclusion, agronomic biofortification of Zn through soil applications at 6.25 mg Zn kg-1 was a sustainable way to improving growth and grain Zn, N, K, Cu and Fe uptake of hybrid rice to meet human recruitment.

References

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  • De Steur, H., Gellynck, X., Blancquaert, D., Lambert, W., Van Der Straeten, D., Qaim, M., 2012. Potential impact and cost-effectiveness of multi-biofortified rice in China. New Biotechnology 29(3): 432-442.
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  • Gupta, N., Ram, H. and Kumar, B., 2016. Mechanism of Zinc absorption in plants: uptake, transport, translocation and accumulation. Reviews in Environmental Science and Bio/Technology 15(1): 89-109.
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  • Hotz, C., Brown, K.H., 2004. Assessment of the risk of zinc deficiency in populations and options for its control. Available at [Access date: 28.10.2021]: https://archive.unu.edu/unupress/food/fnb25-1s-IZiNCG.pdf
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  • Li, B.Y., Zhou, D.M., Cang, L., Zhang, H.L., Fan, X.H., Qin, S.W., 2007. Soil micronutrient availability to crops as affected by long-term inorganic and organic fertilizer applications. Soil and Tillage Research 96(1-2): 166-173.
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  • Liu, W.H., Zhao, J.Z., Ouyang, Z.Y., Söderlund, L., Liu, G.H., 2005. Impacts of sewage irrigation on heavy metal distribution and contamination in Beijing, China. Environment International 31(6): 805-812.
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There are 68 citations in total.

Details

Primary Language English
Journal Section Articles
Authors

Kiran Kumar Mohapatra This is me 0000-0002-4129-0396

Satish Kumar Singh This is me 0000-0001-7321-4630

Abhik Patra This is me 0000-0003-3415-7180

Surendra Singh Jatav This is me 0000-0003-4049-2444

Vishnu D. Rajput This is me 0000-0002-6802-4805

Victoria Popova This is me

Olesya Puzikova This is me

Olga Nazarenko This is me

Svetlana Sushkova This is me 0000-0003-3470-9627

Publication Date July 1, 2022
Published in Issue Year 2022

Cite

APA Mohapatra, K. K., Singh, S. K., Patra, A., Jatav, S. S., et al. (2022). Biogeoaccumulation of zinc in hybrid rice (Oryza sativa L.) in an Inceptisol amended with soil zinc application and its bioavailability to human being. Eurasian Journal of Soil Science, 11(3), 184-197. https://doi.org/10.18393/ejss.1057928