The impact of cerium oxide nanoparticles on tomato (Solanum lycopersicum L.) and its implications for food safety

Wang, Qiang; Ma, Xingmao; Zhang, Wen; Pei, Haochun; Chen, Yongsheng

doi:10.1039/c2mt20149f

Cited by 227 publications

(172 citation statements)

References 35 publications

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“…Interestingly, the authors included an aerial exposure on leaves and although nanoceria could not be washed from the tissue, the particles were not internalized or transferred to new growth. Similarly, Wang et al 81 grew tomato in the presence of nanoceria-amended (0.1-10 mg/l) irrigation water and reported either no impact or slight enhancements in plant growth and yield. The authors did observe ceria in the shoots, including edible tissues, which suggests translocation, but the mechanism and form of element transfer is unknown.…”

Section: Soil Exposures In Plantsmentioning

confidence: 96%

Environmental release, fate and ecotoxicological effects of manufactured ceria nanomaterials

Collin

Auffan

Johnson

et al. 2014

Environ. Sci.: Nano

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105

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uses. This has led to a number of publications on the toxicological effects of nanoceria in ecological receptor species, but only limited information is available on possible environmental releases, concentrations in environmental media, or environmental transformations. Increasing material flows of nanoceria in many applications is likely to result in increasing releases to air, water and soils however; insufficient information was available to estimate aquatic exposures that would result in acute or chronic toxicity. The purpose of this review is to identify which areas are lacking in data to perform either regional or site specific ecological risk assessments. While estimates can be made for releases from use as a diesel fuel additive, and predicted toxicity is low in most terrestrial species tested to date, estimates for releases from other uses are difficult at this stage. We

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Section: Soil Exposures In Plantsmentioning

confidence: 96%

Environmental release, fate and ecotoxicological effects of manufactured ceria nanomaterials

Collin

Auffan

Johnson

et al. 2014

Environ. Sci.: Nano

Self Cite

105

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“…10 NP sizes above active transport ranging from 14 to 40 nm had a large variation in uptake ranging from 0.25 to 3750 μg/g of plant, but typically had accumulation ranging from ∼1−1100 μg/g of plant again with the majority of the NPs contained within the root and with 0.5−183 μg/g in the leaves. 1,15,16,20,27,29 NPs (50 nm), had accumulation in mung bean of 8 μg/g and in wheat of 32 μg/ g. 32 When comparing the accumulation of two similarly sized TiO 2 -NPs of different crystalline structure [22 nm (rutile) and 25 nm (anatase)] in wheat different accumulation amounts were observed, suggesting size was not the only limiting factor for transportation into a plant. 1 In another study using radioactive NPs, Zhang et al 141 Cemetal could dissolute and be transported into the plant, making it appear as if the intact-NPs were in the plant because possible leaching of radioactivity was not explored.…”

Section: ■ Discussionmentioning

confidence: 99%

In Vivo Tracking of Copper-64 Radiolabeled Nanoparticles in Lactuca sativa

Davis

Rippner

Hausner

et al. 2017

Environ. Sci. Technol.

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Engineered nanoparticles (NPs) are increasingly used in commercial products including automotive lubricants, clothing, deodorants, sunscreens, and cosmetics and can potentially accumulate in our food supply. Given their size it is difficult to detect and visualize the presence of NPs in environmental samples, including crop plants. New analytical tools are needed to fill the void for detection and visualization of NPs in complex biological and environmental matrices. We aimed to determine whether radiolabeled NPs could be used as a noninvasive, highly sensitive analytical tool to quantitatively track and visualize NP transport and accumulation in vivo in lettuce (Lactuca sativa) and to investigate the effect of NP size on transport and distribution over time using a combination of autoradiography, positron emission tomography (PET)/computed tomography (CT), scanning electron microscopy (SEM), and transition electron microscopy (TEM). Azide functionalized NPs were radiolabeled via a "click" reaction with copper-64 ( 64 Cu)-1,4,7-triazacyclononane triacetic acid (NOTA) azadibenzocyclooctyne (ADIBO) conjugate ([ 64 Cu]-ADIBO-NOTA) via copper-free Huisgen-1,3-dipolar cycloaddition reaction. This yielded radiolabeled [ 64 Cu]-NPs of uniform shape and size with a high radiochemical purity (>99%), specific activity of 2.2 mCi/mg of NP, and high stability (i.e., no detectable dissolution) over 24 h across a pH range of 5−9. Both PET/CT and autoradiography showed that [ 64 Cu]-NPs entered the lettuce seedling roots and were rapidly transported to the cotyledons with the majority of the accumulation inside the roots. Uptake and transport of intact NPs was size-dependent, and in combination with the accumulation within the roots suggests a filtering effect of the plant cell walls at various points along the water transport pathway.

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“…The authors also included an aerial exposure on leaves, and similarly corn growth was not affected. Wang et al (2012) grew tomato in the presence of CeO 2 NP-amended (0.1-10 mg/L) irrigation water throughout the lifetime of this plant and reported either no impact or slight enhancements in plant growth and yield. A recent study demonstrated that CeO 2 NPs had a modest impact on soybean growth in soil but showed a detrimental impact on the nitrogen fixation bacterial community on soybean roots (Priester et al 2012).…”

Section: Phyto-effect Of Cerium Oxide Nanoparticlesmentioning

confidence: 94%

“…The authors reported that after 14-day exposure with the CeO 2 NPs in the irrigation water (50 mL of 10 μg/mL per day) resulted in no detection of ceria in the leaves or sap of corn plants. In contrast, Wang et al (2012) grew tomato from seeds to the maturity of the plants in the presence of CeO 2 NP-amended (0.1-10 mg/L) irrigation water and reported the detection of ceria in all plant tissues, including tomato fruits, suggesting translocation. Interestingly, the authors also noticed high concentrations of ceria in tomato seeds irrigated with 10 mg/L CeO 2 NP-containing solution than controls.…”

Section: Uptake and Accumulation Of Titanium Dioxidementioning

confidence: 95%

Uptake and Accumulation of Engineered Nanomaterials and Their Phytotoxicity to Agricultural Crops

Gao

2015

Nanotechnologies in Food and Agriculture

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Rapidly expanding world population and dwindling arable land around the world demand innovative technologies to drastically enhance the global crop yield in the near future. The advancement in nanotechnology provides some possibility to achieve this goal. However, the application of nanomaterialcontaining fertilizers and other agricultural products also carries environmental and health risks such as the accumulation of nanomaterial residues in edible tissues, which leads to potential phytotoxicity to agricultural crops and disturbance to the ecosystem. These environmental and health risks need to be well understood before the application of nanotechnology in agriculture can be fully embraced. This chapter presents a summary on the available information concerning the uptake, transport, and accumulation of engineered nanomaterials (ENMs) by agricultural crops and their potential toxicity to these crops. This chapter also discusses the modifications of the fate and transport of coexisting environmental chemicals by ENMs and potential correlations between the unique properties of ENMs with their fate and impact in agricultural systems to shed light on further beneficial applications of ENMs in agriculture.

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The impact of cerium oxide nanoparticles on tomato (Solanum lycopersicum L.) and its implications for food safety

Cited by 227 publications

References 35 publications

Environmental release, fate and ecotoxicological effects of manufactured ceria nanomaterials

Environmental release, fate and ecotoxicological effects of manufactured ceria nanomaterials

In Vivo Tracking of Copper-64 Radiolabeled Nanoparticles in Lactuca sativa

Uptake and Accumulation of Engineered Nanomaterials and Their Phytotoxicity to Agricultural Crops

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