9 | Biology 31.1844/https://doi.org/10.30526 8132(عام 1العدد ) 13هجلة إبن الهيثن للعلىم الصرفة والتطبيقية الوجلد Ibn Al-Haitham Jour. for Pure & Appl. Sci. Vol. 13 (3) 2018 Histopathological Effect of Zinc Oxide Nanoparticles on Kkidney and Liver Tissues in Albino Male Mice Ruqayah Ali Salman University of Al-Forat Al-Awsat Techniques rokayaalibio@gmail.com Received in:4 /July/2017, Accepted in:17/September/2017 Abstract Objective: The present study investigated the effects of different dose levels of Zinc oxide Nanoparticles (ZnO NPs) on the liver and kidney tissues in albino male mice. Methadology: ZnO NPs was administrated as a daily oral dose of (150, 350 mg/kg body weight) gavage for 2 weeks. Eighteen male mices were used by dividing them into three groups. Result: Histopathological examination of kidney and hepatic tissues treated with ZnO NPs showed toxicity changes compared with control group. Conclusion:This study demonstrated the ability of ZnO NPs to effect on kidney and liver tissues. Recommendation: More study needed to know the effect of different doses of nanoparticles on human health. Key words: Nanoparticles, Zinc oxide nanoparticles, Albino male mice, kidney and liver. 01 | Biology 31.1844/https://doi.org/10.30526 8132(عام 1العدد ) 13هجلة إبن الهيثن للعلىم الصرفة والتطبيقية الوجلد Ibn Al-Haitham Jour. for Pure & Appl. Sci. Vol. 13 (3) 2018 Introduction Nanoparticles can enter the human body through the different rolls such as inhalation, ingestion and injection [1]. Then, transolcate to blood causing negative feedback in several organs [2]. Some research looking at biological trace element of the human body and are usually found in foods or added as a food supplement. Zinc concentration determines the toxicity [3]. It is the high concentration of zinc that leads to toxic effect [4]. Other research indicated the histopathological changes of kidney tissues mice treated with ZnO NPs such as hydropic degeneration in epithelial cells, necrosis and glomeruli segmentation [5]. The activity of metal oxides nanoparticles such as zinc oxide (ZnO NPs), silicon oxide and selective toxicity of biological systems proposed potential entail application that includes herapeutics, diagnostics surgical devices and nano medicine based on antimicrobial agents [6]. The increasing production and use of metal oxide nanoparticles in many applications lead to negative effects on health [7]. Several studies have demonstrated nanoparticle toxicity and increased cytotoxic potential of these materials [8]. ZnO NPs can enter bodies water not only through dikardligh dyes and paints but also get rid of cosmetics [9,10]. ZnO is one of the few semiconductors quantum confinement effect and it is an environmental friendly oxide, because of its no toxicity (depended on the concentration and dose) and the ability to absorb in the UV range that use absorbent UV sunscreens in transferring power [11]. Aragon G and Younossi ZM. suggest that the toxicity of NPs depended on species, ZnO NPs significant changes the levels of ALT, ALP and AST enzymes. The elevated of these enzymes are indicative of the functional efficiency of the liver. Due to damaged liver cells, these enzymes are released into the blood, therefore, a high amount of these enzymes indicates destruction of liver cells [12]. In the current study, the effect of different dose levels of Zinc oxide Nanoparticles (ZnO NPs) on kidney and liver tissues in Albino male mice was investigated. Materials and Methods Zinc oxide nanoparticles have been obtained from Nanjing, China. Structure and size measurement of nanoparticles sample were recognized by the Scanning Electron Microscope SEM (Electronic Microscope Center-College of Applied Science, University of Technology, Iraq). Different concentrations of nanoparticles colloids were prepared from stock solution of 300 μg/ml ZnO NPs in (3:1) distill water and ethanol as a solvent. Eighteen albino male mice obtained from the animal house of biotechnological center in Al- Nahrain University. The age of mice was 3 weeks and the weight was 20-25 gm. Animals cages were kept in standardized conditions (25±5 0 C, 12 hr light/ dark cycle). Allow free taken water and pelleted. In this study, the male albino mice were divided into three groups (each group comprises six mice). First group (control group) received food and water. The second and third groups were oral gavages by 150 mg/kg and 350 mg/kg body weight of ZnO NPs. All animals were sacrified at the end of experiment. A small piece of kidney and liver were taken and fixed in 10% formalin solution, after that routine histological preparations was conducted [13]. Results The current study revealed that ZnO NPs (150 mg/kg body weight) induced changes of kidney and liver tissue after 15 days of exposure. Kidney sections of control group showed normal structure; normal renal cortex and normal nephritic tubules figure (1), liver section 00 | Biology 31.1844/https://doi.org/10.30526 8132(عام 1العدد ) 13هجلة إبن الهيثن للعلىم الصرفة والتطبيقية الوجلد Ibn Al-Haitham Jour. for Pure & Appl. Sci. Vol. 13 (3) 2018 showed normal hepatocytes, central vein and hepatic portal traid figure (2). In the second group that treated with (150 mg/kg body weight/ day ZnO NPs) showed pathological changes which includes: medulla revealed slight enlargement in collecting tubules and normal cortex composed in the kidney figures (3) & (4) and proliferation of kupffer cell in the liver figure (5) compared to the control group figure (1) The third group that treated with (350 mg/kg body weight/ day) of Zinc oxide nanoparticles showed marked, inflammatory cells particularly mononuclear cells aggregation around blood vessels and between renal tubules in the kidney figure (4), and amyloid like substance deposition in the wall of liver sinusoids and replacement of hepatic cords deposition in the wall of sinusoids Figure (8). The liver also showed inflammatory cells infiltration particulary nentrophils and mononuclear cells appear around congested blood vessels. Figure (9) Figure (1): Section in mouse kidney of control groups showed normal kidney structures; medulla, collecting tubules (1), lined by simple cuboidal epithelium (2) with normal renal corpuscles with their glomeruli (3). H &E stain 400X Figure (2): Section in mouse liver of control groups showed normal structures of hepatic cord (1), liver sinusoids (2). H &E stain 400X. Figure (3): Section in mouse kidney of animal treated with 150 mg/kg body weight/ day of ZnO NPs for 15 days showed reveal slight enlargement in collecting tubules. H &E stain 400X. Figure (4): Section in mouse kidney cortex of animal treated with 150 mg/kg body weight/ day of ZnO NPs for 15 days showed normal glomeruli (1), normal convoluted tubules (2). H &E stain 400X. 01 | Biology 31.1844/https://doi.org/10.30526 8132(عام 1العدد ) 13هجلة إبن الهيثن للعلىم الصرفة والتطبيقية الوجلد Ibn Al-Haitham Jour. for Pure & Appl. Sci. Vol. 13 (3) 2018 Figure (5): Section in mouse liver of animal treated with 150 mg/kg body weight/ day of ZnO NPs for 15 days showed proliferation of kupffer cells. H &E stain 400X. Figure (6): Section in mouse kidney of animal treated with 350 mg/kg body weight/ day of ZnO NPs for 15 days showed marked inflammatory cells particularly mononuclear cells aggregation around blood vessels and I between renal tubules. H & E stain 400X. Figure (7): Section in mouse kidney of animal treated with 350 mg/kg body weight/ day of ZnO NPs for 15 days showed proteinous material in the lumen of renal tubules. H & E stain 400X. Figure (8): Section in mouse liver of animal treated with 350 mg/kg body weight/ day of ZnO NPs for 15 days showed amyloid like substance deposition in the wall of sinusoids and replacement of hepatic cords deposition in the wall of sinusoids. H & E stain 400X. Figure (9): Section in mouse liver of animal treated with 350 mg/kg body weight/ day of ZnO NPs for 15 days showed inflammatory cells infiltration particularly neutrophils and mononuclear cells around congested blood vessels. H &E stain 400X. 02 | Biology 31.1844/https://doi.org/10.30526 8132(عام 1العدد ) 13هجلة إبن الهيثن للعلىم الصرفة والتطبيقية الوجلد Ibn Al-Haitham Jour. for Pure & Appl. Sci. Vol. 13 (3) 2018 Discussion The small sizes of the particles have the ability to enter and damage the organism allows to penetrate the physiological barriers traveling with circulatory systems [14]. The study found that oral exposure to nano-forms of different particles was more toxic than micro-counterparts [15]. This study investigates the effect of ZnO NPs on the kidney and liver tissues. It can spread more in blood, kidney, liver and other organs [16]. This study agrees with Sharma V. et al results [17] showed that oral acute exposure to ZnO NPs causes apoptosis in mice liver cells and induces severe oxidative stress. Histopathological section showed that ZnO NPs is able to induce changes in tissues of kidney and liver in albino male mice. Liver damage could be induced due to excess oral ZnO NPs, and this agrees with another study in 2012 [18]. The histo-toxicity of ZnO NPs in high doses (350 mg/kg body weight/ day) was more than in low doses (150 mg/kg body weight/ day) in kidney and liver tissues. Dietary exposure to titanium dioxide NPs caused liver toxicity and resulted in un activity of mice liver catalogs homogenate GOT [19]. Other studies have demonstrated that pathogenic mechanisms initiated by some NPs were dominated by inflammation-driven effects, which occurred due to the oxidative stress or DNA damage [20], This explains the influence of oxidative stress in cellular death by necrosis or degeneration in the mouse kidney and liver treated with ZnO NPs. Conclusion This study demonstrated the ability of ZnO NPs to effect on kidney and liver by causing pathological changes in these organs. Recommendation Further studies are needed to determine the effect of ZnO NPs on liver enzymes, blood parameters and histological study to other organs. References [1] B A. Koeneman; Y. Zhang; P. Westerhoff; Y. Chen, and J C. Crittenden, Toxicity and cellular responses of intestinal cells exposed to titanium dioxide. Cell Biol. Toxicol. 26:225-238, 2010. [2] HJ. Johnston; G. Hutchison; FM. Christensen; S. Peters, and S. 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