Decreased dissolution of ZnO by iron doping yields nanoparticles with reduced toxicity in the rodent lung and zebrafish embryos.

We have recently shown that the dissolution of ZnO nanoparticles and Zn(2+) shedding leads to a series of sublethal and lethal toxicological responses at the cellular level that can be alleviated by iron doping. Iron doping changes the particle matrix and slows the rate of particle dissolution. To determine whether iron doping of ZnO also leads to lesser toxic effects in vivo, toxicity studies were performed in rodent and zebrafish models. First, we synthesized a fresh batch of ZnO nanoparticles doped with 1-10 wt % of Fe. These particles were extensively characterized to confirm their doping status, reduced rate of dissolution in an exposure medium, and reduced toxicity in a cellular screen. Subsequent studies compared the effects of undoped to doped particles in the rat lung, mouse lung, and the zebrafish embryo. The zebrafish studies looked at embryo hatching and mortality rates as well as the generation of morphological defects, while the endpoints in the rodent lung included an assessment of inflammatory cell infiltrates, LDH release, and cytokine levels in the bronchoalveolar lavage fluid. Iron doping, similar to the effect of the metal chelator, DTPA, interfered in the inhibitory effects of Zn(2+) on zebrafish hatching. In the oropharyngeal aspiration model in the mouse, iron doping was associated with decreased polymorphonuclear cell counts and IL-6 mRNA production. Doped particles also elicited decreased heme oxygenase 1 expression in the murine lung. In the intratracheal instillation studies in the rat, Fe doping was associated with decreased polymorphonuclear cell counts, LDH, and albumin levels. All considered, the above data show that Fe doping is a possible safe design strategy for preventing ZnO toxicity in animals and the environment.

[1]  J. Chen,et al.  Global Gene Expression Profiling in Whole-Blood Samples from Individuals Exposed to Metal Fumes , 2004, Environmental health perspectives.

[2]  James E Hutchison,et al.  Greener nanoscience: a proactive approach to advancing applications and reducing implications of nanotechnology. , 2008, ACS nano.

[3]  X. M. Wu,et al.  Structure and photoluminescence properties of Fe-doped ZnO thin films , 2006 .

[4]  David B Warheit,et al.  Assessing toxicity of fine and nanoparticles: comparing in vitro measurements to in vivo pulmonary toxicity profiles. , 2007, Toxicological sciences : an official journal of the Society of Toxicology.

[5]  Thomas D. Schmittgen,et al.  Analysis of relative gene expression data using real-time quantitative PCR and the 2(-Delta Delta C(T)) Method. , 2001, Methods.

[6]  L C Chen,et al.  Metal fume fever: characterization of clinical and plasma IL-6 responses in controlled human exposures to zinc oxide fume at and below the threshold limit value. , 1997, Journal of occupational and environmental medicine.

[7]  L C ROHRS,et al.  Metal-fume fever from inhaling zinc oxide. , 1957, A.M.A. archives of industrial health.

[8]  B. Fubini,et al.  Surface reactivity in the pathogenic response to particulates. , 1997, Environmental health perspectives.

[9]  Benjamin Gilbert,et al.  Comparison of the mechanism of toxicity of zinc oxide and cerium oxide nanoparticles based on dissolution and oxidative stress properties. , 2008, ACS nano.

[10]  D. Furgeson,et al.  Zebrafish as a correlative and predictive model for assessing biomaterial nanotoxicity. , 2009, Advanced drug delivery reviews.

[11]  Watze de Wolf,et al.  Animal Use Replacement, Reduction, and Refinement: Development of an Integrated Testing Strategy for Bioconcentration of Chemicals in Fish , 2007, Integrated environmental assessment and management.

[12]  L. Zon,et al.  In vivo drug discovery in the zebrafish , 2005, Nature Reviews Drug Discovery.

[13]  Andre E Nel,et al.  Tracheobronchial particle dose considerations for in vitro toxicology studies. , 2006, Toxicological sciences : an official journal of the Society of Toxicology.

[14]  Xuezhi Zhang,et al.  The impact of ZnO nanoparticle aggregates on the embryonic development of zebrafish (Danio rerio) , 2009, Nanotechnology.

[15]  R. Altenburger,et al.  A novel in vitro system for the determination of bioconcentration factors and the internal dose in zebrafish (Danio rerio) eggs. , 2009, Chemosphere.

[16]  Mark R Wiesner,et al.  Comparison of the abilities of ambient and manufactured nanoparticles to induce cellular toxicity according to an oxidative stress paradigm. , 2006, Nano letters.

[17]  Jeffrey I. Zink,et al.  Dispersion and stability optimization of TiO2 nanoparticles in cell culture media. , 2010, Environmental science & technology.

[18]  K. Nagata,et al.  Crystal structure of zebrafish hatching enzyme 1 from the zebrafish Danio rerio. , 2010, Journal of molecular biology.

[19]  Lutz Mädler,et al.  Flame sprayed visible light-active Fe-TiO2 for photomineralisation of oxalic acid , 2007 .

[20]  T. Gordon,et al.  Rat lung metallothionein and heme oxygenase gene expression following ozone and zinc oxide exposure. , 1992, Toxicology and applied pharmacology.

[21]  X Zhang,et al.  Zinc exposure in Chinese foundry workers. , 1999, American journal of industrial medicine.

[22]  M. Elimelech,et al.  Aggregation kinetics of alginate-coated hematite nanoparticles in monovalent and divalent electrolytes. , 2006, Environmental science & technology.

[23]  Y. Oytam,et al.  Small amounts of zinc from zinc oxide particles in sunscreens applied outdoors are absorbed through human skin. , 2010, Toxicological sciences : an official journal of the Society of Toxicology.

[24]  L. Mädler,et al.  Nanorods of ZnO Made by Flame Spray Pyrolysis , 2006 .

[25]  Lung-Chi Chen,et al.  Quantitative trait analysis of the development of pulmonary tolerance to inhaled zinc oxide in mice , 2005, Respiratory research.

[26]  Meiying Wang,et al.  The Adjuvant Effect of Ambient Particulate Matter Is Closely Reflected by the Particulate Oxidant Potential , 2009, Environmental health perspectives.

[27]  M Boller,et al.  Synthetic TiO2 nanoparticle emission from exterior facades into the aquatic environment. , 2008, Environmental pollution.

[28]  T. Tyliszczak,et al.  Nanoscale environments associated with bioweathering of a Mg-Fe-pyroxene. , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[29]  David M. Brown,et al.  Proinflammogenic Effects of Low-Toxicity and Metal Nanoparticles In Vivo and In Vitro: Highlighting the Role of Particle Surface Area and Surface Reactivity , 2007, Inhalation toxicology.

[30]  Saji George,et al.  A predictive toxicological paradigm for the safety assessment of nanomaterials. , 2009, ACS nano.

[31]  Vincent Castranova,et al.  A biocompatible medium for nanoparticle dispersion , 2008 .

[32]  Zhong Chen,et al.  Structure, morphology and properties of Fe-doped ZnO films prepared by facing-target magnetron sputtering system , 2009 .

[33]  David B Warheit,et al.  Pulmonary bioassay studies with nanoscale and fine-quartz particles in rats: toxicity is not dependent upon particle size but on surface characteristics. , 2007, Toxicological sciences : an official journal of the Society of Toxicology.

[34]  N. Yoshizaki,et al.  Purification and characterization of zebrafish hatching enzyme – an evolutionary aspect of the mechanism of egg envelope digestion , 2008, The FEBS journal.

[35]  David B Warheit,et al.  Long-term pulmonary responses of three laboratory rodent species to subchronic inhalation of pigmentary titanium dioxide particles. , 2002, Toxicological sciences : an official journal of the Society of Toxicology.

[36]  Vincent Castranova,et al.  Improved method to disperse nanoparticles for in vitro and in vivo investigation of toxicity , 2007 .

[37]  J. Teyssie,et al.  Differential bioaccumulation behaviour of Ag and Cd during the early development of the cuttlefish Sepia officinalis. , 2008, Aquatic toxicology.

[38]  Benjamin Gilbert,et al.  Use of a rapid cytotoxicity screening approach to engineer a safer zinc oxide nanoparticle through iron doping. , 2010, ACS nano.

[39]  F. Eddy Osmotic properties of the perivitelline fluid and some properties of the chorion of Atlantic salmon eggs (Salmo salar) , 2009 .

[40]  A. Kahru,et al.  From ecotoxicology to nanoecotoxicology. , 2010, Toxicology.

[41]  P. Baron,et al.  Inhalation vs. aspiration of single-walled carbon nanotubes in C57BL/6 mice: inflammation, fibrosis, oxidative stress, and mutagenesis. , 2008, American journal of physiology. Lung cellular and molecular physiology.

[42]  A. Dicker,et al.  Zebrafish: An Emerging Model System for Human Disease and Drug Discovery , 2007, Clinical pharmacology and therapeutics.

[43]  Prakash D Nallathamby,et al.  In vivo imaging of transport and biocompatibility of single silver nanoparticles in early development of zebrafish embryos. , 2007, ACS nano.

[44]  Wei Bai,et al.  Toxicity of zinc oxide nanoparticles to zebrafish embryo: a physicochemical study of toxicity mechanism , 2010 .

[45]  Shuo Lin,et al.  Genetic analysis of early endocrine pancreas formation in zebrafish. , 2006, Molecular endocrinology.

[46]  T. Xia,et al.  Toxic Potential of Materials at the Nanolevel , 2006, Science.

[47]  S. Wesselkamper,et al.  Development of pulmonary tolerance in mice exposed to zinc oxide fumes. , 2001, Toxicological sciences : an official journal of the Society of Toxicology.

[48]  W. Brack,et al.  Zinc and cadmium accumulation in single zebrafish (Danio rerio) embryos — A total reflection X-ray fluorescence spectrometry application , 2008 .

[49]  J. Crapo,et al.  Allometric relationships of cell numbers and size in the mammalian lung. , 1992, American journal of respiratory cell and molecular biology.