Nanotechnology in Plant Growth Promotion and Protection. Группа авторов

Nanotechnology in Plant Growth Promotion and Protection - Группа авторов


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exposure experiment (Moll et al. 2016).

Size (diameter in nm) Plant species, length of exposure Effect of concentration Impact References
No effect Positive Negative
n.a. Spinacia oleraces, 48 h n.a. 250–4000 mg/L 4000−8000 mg/L Increased germination, germination index, seedling dry weight, vigor indexDecreased germination, germination index, seedling dry weight, vigor index Zheng et al. (2005)
5 Spinacia oleraces, 48 h n.a. 300 mg/L n.a. Increase in plant fresh and dry weightIncrease in amount of Rubisco activase Gao et al. (2008)
n.a. Oryza sativa, 24–72 h 100, 500, 1000 mg/L n.a. n.a. Slight decrease in root length at 2‐ and 3‐day exposure Boonyanitipong et al. (2011)
<50 Cucumis sativus, 6 days n.a. n.a. 100–5000 mg/L Decrease in germination, germination index Mushtaq (2011)
<100 Vicia narbonensis, Zea mays 24 h n.a. n.a. 200–4000 mg/L Decrease in root elongationDecrease in mitotic indexIncrease in aberration index Ruffini Castiglione et al. (2011)
21 a Triticum aestivum, 8 days 1, 100, 500 mg/L 2, 10 mg/L n.a. Mean germination time loweredIncrease in shoot length Feizi et al. (2012)
21 a Foeniculum vulgare, 14 days 80 mg/L 5, 20, 40, 60 mg/L n.a. Mean germination time loweredGermination percentage, germination value, vigor index and mean daily germination improved Feizi et al. (2013b)
21 a Salvia officinalis, 21 days 5, 20, 40, 80 mg/L 60 mg/L n.a. Mean germination time loweredGermination percentage improved Feizi et al. (2013a)
15, 25, 32 Linum usitatissimum, 24 h seed germination, 48 h root biomass, 72 h root biomass, and length n.a. 100 mg/L (25 and 32 nm only) 0.01−100 mg/L Inhibition of germinationDecrease in root length and biomassIncrease in root growth and germination (25 and 32 nm only) Clément et al. (2013)
27 Solanum lycopersicum, 48 h 50–5000 mg/L n.a. n.a. No effect on germination Song et al. (2013)
35 Pisum sativum, 24 h 100, 250, 500, 750, 1000 mg/L n.a. n.a. No effect on the germination Fan et al. (2014)
25 a Nicotiana tabacum, 21 days n.a. n.a. 1000, 10 000 mg/L Decrease in root lengthChanges in microRNA expression Frazier et al. (2014)
25 a Hordeum vulgare 7 days 500, 1000 mg/L n.a. 2000 mg/L Elevated reactive oxygen species within plant Mattiello et al. (2015)
23 a Allium cepa, Avena sativa, Brassica oleracea capitate, Cucumis sativus, Daucus carota, Glycine max, Lactuca sativa, Lolium perenne, Solanum lycopersicum, Zea mays, 24 h + variable time period 250, 500, 1000 mg/L 250 mg/L (B. oleracea) 500 mg/L (B. oleracea, A. cepa) 1000 mg/L (A, sativa, C. sativus, A. cepa) 250 mg/L (C. sativus, G. max, Z. mays) 500 mg/L (A. sativa, Z. mays) 1000 mg/L (C. sativus, Z. mays) Decreased or increased germination (4 species)Decreased or increased cotyledon presence (4 species)Decreased or increased average root length (6 species) Andersen et al. (2016)
21, 10 nm and 10 000 nm nanowire Sinapis alba, 72 h 10, 100, 1000 mg/L n.a. n.a. No effect on germination Landa et al. (2016)
<10, <100 Vicia faba, 72 h n.a. 50 mg/L (<10 nm) 50 mg/L (<100 nm) Stimulation of germination process (<10 nm)Oxidative stress, genotoxicity (<100 nm) Ruffini Castiglione et al. (2016)

      n.a: Not available

      a Both seed treatment and prolonged exposure.

Size (diameter in nm) Plant species, length of exposure
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