Assessing the toxicity and accumulation of bulk- and nano-CuO in Hordeum sativum L

The effects of bulk- and nano-CuO were monitored on barley ( Hordeum sativum L.) in hydroponic conditions. The anatomical and cyto-/morphometric parameters of plants, exposed to both types of CuO in different doses (300 and 2000 mg/L) were recorded. The germination rate, root and shoot lengths decre...

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Bibliographic Details
Published in:Environmental geochemistry and health 2021-06, Vol.43 (6), p.2443-2454
Main Authors: Rajput, Vishnu, Chaplygin, Victor, Gorovtsov, Andrey, Fedorenko, Alexey, Azarov, Anatoly, Chernikova, Natalya, Barakhov, Anatoly, Minkina, Tatiana, Maksimov, Alexey, Mandzhieva, Saglara, Sushkova, Svetlana
Format: Article
Language:English
Subjects:
Accumulation
Barley
Bioaccumulation
Cells
Chloroplasts
Copper oxides
Cylinders
Dosage
Earth and Environmental Science
Environment
Environmental Chemistry
Environmental Health
Geochemistry
Germination
Hordeum sativum
Hydroponics
Morphometry
Nanoparticles
Original Paper
Particle size
Plant tissues
Public Health
Seed germination
Soil Science & Conservation
Terrestrial Pollution
Toxicity
Translocation
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Summary:The effects of bulk- and nano-CuO were monitored on barley ( Hordeum sativum L.) in hydroponic conditions. The anatomical and cyto-/morphometric parameters of plants, exposed to both types of CuO in different doses (300 and 2000 mg/L) were recorded. The germination rate, root and shoot lengths decreased in a dose-dependent manner. Exposure to nano-CuO significantly increased Cu content in the H. sativum roots; however, the translocation rates of dissolved Cu were low and showed less accumulation in above-ground tissues. The differences between nano- and bulk-CuO treated plants were sufficiently evident, but at lower concentrations, these differences were non-significant. The relative seed germination inhibition was noted up to 11% and 22% under the high dose of bulk- and nano-CuO, respectively; however, at low dose, it was non-significant. The relative root length was reduced 3.6 fold by bulk- and 1.5 fold by nano-CuO, and shoot lengths decreased 1.6 fold by bulk- and 1.4 fold by nano-CuO under the high dose after growth of 30 days. It indicated more morphological effects on H. sativum caused by bulk- than the nano-CuO. The cytomorphometric analysis indicated the average cortex cell, total cortex, and total central cylinder areas of root cells and the average areas of chlorenchyma leaf cells were increased as compared to control in both bulk- and nano-CuO treated plants. It showed destructive effects of nano- and bulk-CuO on cellular organizations of H. sativum anatomy . Thus, at the low dose, the minimal effects of nano-CuO were observed than the bulk. Therefore, the finding could be interest for the safe application of nano-CuO.
ISSN:0269-4042
1573-2983
DOI:10.1007/s10653-020-00681-5