The Possibility of Using S. Y. Hu × Hybrid for Phytoextraction of Toxic Elements from Post-Industrial Wastes with Biochar

Overview

Journal Plants (Basel)

Date 2021 Oct 23

PMID 34685857

Citations 1

Authors

Kinga Drzewiecka

Monika Gasecka

Zuzanna Magdziak

Sylwia Budzynska

Malgorzata Szostek

Przemyslaw Niedzielski

Anna Budka

Edward Roszyk

Beata Doczekalska

Marta Gorska

Miroslaw Mleczek

Affiliations

Soon will be listed here.

Abstract

The potential of the hybrid for the uptake and transport of 67 elements along with the physiological response of plants cultivated in highly contaminated post-industrial wastes (flotation tailings-FT, and mining sludge-MS) was investigated. Biochar (BR) was added to substrates to limit metal mobility and facilitate plant survival. could effectively uptake and translocate B, Ca, K, P, Rb, Re and Ta. Despite severe growth retardation, chlorophyll biosynthesis was not depleted, while an increased carotenoid content was noted for plants cultivated in waste materials. In leaves and roots hydroxybenzoic acids (C6-C1) were dominant phenolics, and hydroxycinnamic acids/phenylpropanoids (C6-C3) and flavonoids (C6-C3-C6) were also detected. Plant cultivation in wastes resulted in quantitative changes in the phenolic fraction, and a significant drop or total inhibition of particular phenolics. Cultivation in waste materials resulted in increased biosynthesis of malic and succinic acids in the roots of FT-cultivated plants, and malic and acetic acids in the case of MS/BR substrate. The obtained results indicate that the addition of biochar can support the adaptation of seedlings growing on MS, however, in order to limit unfavorable changes in the plant, an optimal addition of waste is necessary.

Citing Articles

An Assessment of the Phytoremediation Potential of Planted and Spontaneously Colonized Woody Plant Species on Chronosequence Fly Ash Disposal Sites in Serbia-Case Study.

Kostic O, Gajic G, Jaric S, Vukov T, Matic M, Mitrovic M Plants (Basel). 2022; 11(1).

PMID: 35009113 PMC: 8747270. DOI: 10.3390/plants11010110.

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