Solubility of nano‐zinc oxide in environmentally and biologically important matrices

Reed, Robert B.; Ladner, David A.; Higgins, Christopher; Westerhoff, Paul; Ranville, James F.

doi:10.1002/etc.708

Cited by 254 publications

(190 citation statements)

References 38 publications

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“…Surface charge and aggregation tend to vary with pH, where the further the environmental pH is from the ENM's PzC, the farther the surface charge is from zero. This increases their stability, since like charges will repel Judy et al 2011;Reed et al 2012;Wang et al 2011). However, high IS can minimize the forces keeping NPs separate and cause aggregation and sedimentation (French et al 2009;Handy et al 2008) even for a pH that is far from the PzC.…”

Section: Aggregation In Watermentioning

confidence: 99%

“…Conversely, the zeta potential for TiO 2 at 10 mM CaCl 2 is close to zero at pH 7 (Petosa et al 2012). The zeta potential for ZnO seems to vary significantly from very positive to very negative at pH values ranging from 4 to 10 (Jiang et al 2009a, b;Petosa et al 2012;Reed et al 2012). The zeta potentials for Au and Cu/CuO tend to be close to zero for a pH between 5.5 and 8.5, except in groundwater for Au and in algal growth media for Cu/CuO (Griffitt et al 2008;Hitchman et al 2013;Judy et al 2011;Wang et al 2011).…”

Section: Aggregation In Watermentioning

confidence: 99%

“…With the exception of ZnO in seawater (Fairbairn et al 2011;Li et al 2013;Miller et al 2010;Xia et al 2008) and freshwater (Franklin et al 2007;Li et al 2013;Mortimer et al 2010;Reed et al 2012), NP dissolution is generally slow, occurring over the course of weeks or months, if at all. Dissolution of ZnO is highly pH dependent and the presence of phosphate can significantly alter the rate of dissolution so that it can be either very high or very low (Blinova et al 2010;Montes et al 2012).…”

Section: Dissolution In Watermentioning

confidence: 99%

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Emerging patterns for engineered nanomaterials in the environment: a review of fate and toxicity studies

2014

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A comprehensive assessment of the environmental risks posed by engineered nanomaterials (ENMs) entering the environment is necessary, due in part to the recent predictions of ENM release quantities and because ENMs have been identified in waste leachate. The technical complexity of measuring ENM fate and transport processes in all environments necessitates identifying trends in ENM processes. Emerging information on the environmental fate and toxicity of many ENMs was collected to provide a better understanding of their environmental implications. Little research has been conducted on the fate of ENMs in the atmosphere; however, most studies indicate that ENMs will in general have limited transport in the atmosphere due to rapid settling. Studies of ENM fate in realistic aquatic media indicates that in general, ENMs are more stable in freshwater and stormwater than in seawater or groundwater, suggesting that transport may be higher in freshwater than in seawater. ENMs in saline waters generally sediment out over the course of hours to days, leading to likely accumulation in sediments. Dissolution is significant for specific ENMs (e.g., Ag, ZnO, copper ENMs, nano zero-valent iron), which can result in their transformation from nanoparticles to ions, but the metal ions pose their own toxicity concerns. In soil, the fate of ENMs is strongly dependent on the size of the ENM aggregates, groundwater chemistry, as well as the pore size and soil particle size. Most groundwater studies have focused on unfavorable deposition conditions, but that is unlikely to be the case in many natural groundwaters with significant ionic strength due to hardness or salinity. While much still needs to be better understood, emerging patterns with regards to ENM fate, transport, and exposure combined with emerging information on toxicity indicate that risk is low for most ENMs, though current exposure estimates compared with current data on toxicity indicates that at current production and release levels, exposure to Ag, nZVI, and ZnO may cause toxicity to freshwater and marine species.

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Section: Aggregation In Watermentioning

confidence: 99%

Section: Aggregation In Watermentioning

confidence: 99%

Section: Dissolution In Watermentioning

confidence: 99%

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Emerging patterns for engineered nanomaterials in the environment: a review of fate and toxicity studies

2014

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“…22,27,28 In order to assess whether the effect induced by ZnO Nps on Jurkat cells was due to the Np itself or to the Zn 2+ ions released by the particles, the cells were exposed to ZnCl 2 salt at three different concentrations (1, 10, and 100 µg/mL Zn 2+ ) and the MAPK and NFκB activation was assessed in Western blots.…”

Section: Effect Of Zn 2+ Ions On the Activation Pathway Induced By Znmentioning

confidence: 99%

Metal oxide nanoparticles interact with immune cells and activate different cellular responses

Simón‐Vázquez¹,

Lozano‐Fernández²,

Dávila-Grana³

et al. 2016

IJN

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Besides cell death, nanoparticles (Nps) can induce other cellular responses such as inflammation. The potential immune response mediated by the exposure of human lymphoid cells to metal oxide Nps (moNps) was characterized using four different moNps (CeO 2 , TiO 2 , Al 2 O 3 , and ZnO) to study the three most relevant mitogen-activated protein kinase subfamilies and the nuclear factor kappa-light-chain-enhancer of the activated B-cell inhibitor, IκBα, as well as the expression of several genes by immune cells incubated with these Nps. The moNps activated different signaling pathways and altered the gene expression in human lymphocyte cells. The ZnO Nps were the most active and the release of Zn 2+ ions was the main mechanism of toxicity. CeO 2 Nps induced the smallest changes in gene expression and in the IκBα protein. The effects of the particles were strongly dependent on the type and concentration of the Nps and on the cell activation status prior to Np exposure.

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“…For example, titanium dioxide nanoparticles (nano-TiO 2 ) were assumed to be practically insoluble in freshwater in many studies, [8], [9] while they were confirmed being able to dissolve in acid aqueous NaCl solutions (pH < 3) at temperatures of 25 and 37 ℃. [10] Dissolution of zinc oxide nanoparticles (nano-ZnO) was observed with 7.18-7.40 mg/L dissolved Zn in pure water, but with much higher dissolved Zn concentration (> 34 mg/L) in a cell culture medium [11].…”

Section: Introductionmentioning

confidence: 99%

Influence of Dissolution on Fate of Nanoparticles in Freshwater

Pu¹,

Laratte²,

Ionescu³

2017

IJESD

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Solubility of nano‐zinc oxide in environmentally and biologically important matrices

Cited by 254 publications

References 38 publications

Emerging patterns for engineered nanomaterials in the environment: a review of fate and toxicity studies

Emerging patterns for engineered nanomaterials in the environment: a review of fate and toxicity studies

Metal oxide nanoparticles interact with immune cells and activate different cellular responses

Influence of Dissolution on Fate of Nanoparticles in Freshwater

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