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Effect of cerium dioxide nanoparticles on metabolic processes in the body of broiler chickens
The scope of application of cerium dioxide and its special physical and chemical properties are considered in the work. The effect of the size factor on the properties of nanodispersed cerium dioxide determines the biological activity of the material, low toxicity and high oxygen non-stoichiometry. Specific properties of CeO2 include the ability to regenerate oxygen non-stoichiometry, which is expressed in the ability of cerium dioxide nanoparticles to return to their initial state after participating in the redox process in a relatively short period of time, which enables their repeated use. Nanoparticles, due to their small size, easily penetrate into the body through the respiratory, digestive, and skin organs and exhibit more pronounced biological activity due to the large surface area per unit mass. The change in the physical and chemical mechanisms of action of nanoparticles is due to the fact that most of the atoms are on the surface. Such an arrangement changes the physical, chemical, biological, toxicological properties of the substance and facilitates the interaction of nanoparticles with a living organism. Once inside a biological system, nanoparticles come into contact with a number of physical and chemical features of the organism, which affect their properties and can change the response. These features are largely due to the ability to pass through the redox cycle between two natural oxidation states (Ce3+ and Ce4+). The influence of cerium dioxide nanoparticles on metabolic processes in the body of broiler chickens has been established. Their introduction contributed to an increase in the content of total lipids in the blood by 24.6–31.3 %, albumins – by 16–22 %, and a decrease in the content of uric acid to the level of 63–67 % of the control. Non-toxicity of poultry meat treated with nano-cerium for consumers was established. The high degree of biocompatibility, low toxicity and catalytic activity of nanodispersed cerium dioxide make it possible to consider it as a promising nanobiomaterial for use in biology, medicine and agriculture.
Key words: nanobiotechnologies, nanoparticles, ceriumdioxide, layinghens, lipids.
- Aneggi, E., de Leitenburg, C., Boaro, M., Fornasiero, P., Trovarelli, A. (2020). Catalytic applications of cerium dioxide. In Cerium Oxide (CeO2): Synthesis, Properties and Applications. Elsevier, pp. 45–108.
- Bao, Y., Pan, C., Liu, W., Li, Y., Ma, C., Xing, B. (2019). Iron plaque reduces cerium uptake and translocation in rice seedlings (Oryza sativa L.) exposed to CeO 2 nanoparticles with different sizes. Science of the Total Environment. 661, pp. 767–777.
- Bityutskyy, V.S., Tsekhmistrenko, О.S., Tsekhmistrenko, S.I., Spyvack, M.Y., Shadura, U.M. (2017). Perspectives of cerium nanoparticles use in agriculture. The Animal Biology, 19(3), pp. 9–17.
- Bubnov, R., Babenko, L., Lazarenko, L., Kryvtsova, M., Shcherbakov, O., Zholobak, N., Spivak, M. (2019). Can tailored nanoceria act as a prebiotic? Report on improved lipid profile and gut microbiota in obese mice. EPMA Journal, 10(4), pp. 317–335.
- Cheng, Y., Xie, Y., Shi, L., Xing, Y., Guo, S., Gao, Y., Shi, B. (2022). Effects of rare earth-chitosan chelate on growth performance, antioxidative and immune function in broilers. Italian Journal of Animal Science, 21(1), pp. 303–313.
- Estevez, A.Y., Ganesana, M., Trentini, J.F., Olson, J. E., Li, G., Boateng, Y.O., Lipps, J.M., Yablonski, S.E.R., Erlichman, J.S. (2019). Antioxidant Enzyme-Mimetic Activity and Neuroprotective Effects of Cerium Oxide Nanoparticles Stabilized with Various Ratios of Citric Acid and EDTA. Biomolecules. 9(10), 562 p.
- Gouhua, L., Pirzado, S.A. (2020). Effect of Azomite With Low Energy Diet On Growth, Carcass Performance and Blood Biochemical Indexes In Broiler Chickens. Journal of Aquaculture & Livestock Production, SRC/JALP-105, 3 p.
- Gunawan, C., Lord, M.S., Lovell, E., Wong, R.J., Jung, M.S., Mann, R., Amal, R. (2019). Oxygen-vacancy engineering of cerium-oxide nanoparticles for antioxidant activity. ACS omega. 4(5), pp. 9473–9479.
- Kobyliak, N., Virchenko, O., Falalyeyeva, T., Kondro, M., Beregova, T., Bodnar, P., Shcherbakov, R., Bubnov, M., Caprnda, D., Sabo, J. (2017). Cerium dioxide nanoparticles possess anti-inflammatory properties in the conditions of the obesity-associated NAFLD in rats. Biomedicine & Pharmacotherapy, 90, pp. 608–614.
- Loddo, V., Yurdakal, S., Parrino, F. (2020). Economical aspects, toxicity, and environmental fate of cerium oxide. In Cerium Oxide (CeO₂): Synthesis, Properties and Applications. Elsevier. pp. 359–373.
- Melchionna, M., Trovarelli, A., Fornasiero, P. (2020). Synthesis and properties of cerium oxide-based materials. In Cerium Oxide (CeO₂): Synthesis, Properties and Applications. Elsevier. pp. 13–43.
- Parra-Robert, M., Casals, E., Massana, N., Zeng, M., Perramón, M., Fernández-Varo, G., Morales-Ruiz, M., Puntes, V., Casals, G. (2019). Beyond the Scavenging of Reactive Oxygen Species (ROS): Direct effect of cerium oxide nanoparticles in reducing fatty acids content in an In vitro Model of Hepatocellular Steatosis. Biomolecules, 9(9), 425 p.
- Reka, D., Thavasiappan, V., Selvaraj, P., Arivuchelvan, A., Visha, P. (2019). Influence of rare earth elements on production performance in post peaklayer chickens. J. Entomol. Zool. Stud, 7(2), pp. 292–295.
- Röhder, L.A., Brandt, T., Sigg, L., Behra, R. (2014). Influence of agglomeration of cerium oxide nanoparticles and speciation of cerium (III) on short term effects to the green algae Chlamydomonas reinhardtii. Aquatic toxicology, 152, pp. 121–130.
- Römer, I., Briffa, S.M., Arroyo Rojas Dasilva, Y., Hapiuk, D., Trouillet, V., Palmer, R.E., Valsami-Jones, E. (2019). Impact of particle size, oxidation state and capping agent of different cerium dioxide nanoparticles on the phosphate-induced transformations at different pH and concentration. PLoSOne, 14(6), e0217483.
- Roudbaneh, S.Z.K., Kahbasi, S., Sohrabi, M.J., Hasan, A., Salihi, A., Mirzaie, A., Falahati, M. (2019). Albumin binding, antioxidant and antibacterial effects of cerium oxide nanoparticles. Journal of Molecular Liquids, 296, 111839 p.
- Scirè, S., Palmisano, L. (2020). Cerium and cerium oxide: A brief introduction. In Cerium Oxide (CeO₂): Synthesis, Properties and Applications. Elsevier. 19, pp. 1–12.
- Shcherbakov, A.B., Zholobak, N.M., Ivanov, V.K. (2020). Biological, biomedical and pharmaceutical applications of cerium oxide. In Cerium Oxide (CeO2): Synthesis, Properties and Applications. Elsevier. pp. 279–358.
- Suman, T.Y., Pei, D.S. (2022). Nanomaterial waste management. In Nanomaterials Recycling. Elsevier. pp. 21–36.
- Tsekhmistrenko, O.S., Bityutskyy, V.S., Tsekhmistrenko, S.I., Spivak, M.Y. (2020). Influence of cerium dioxide nanoparticles on biochemical indicators in the organism of broiler chicken. Veterinary science, technologies of animal husbandry and nature management. 6, pp. 112–117.
- Zholobak, N.M., Shcherbakov, A.B., Ivanova, O.S., Reukov, V., Baranchikov, A.E., Ivanov, V.K. (2020). Nanoceria-curcumin conjugate: Synthesis and selective cytotoxicity against cancer cells under oxidative stress conditions. Journal of Photochemistry and Photobiology B: Biology, 209, 111921 p.
- Bityutskyy, V.S., Spivak, M.Ya., Tsekhmistrenko, O.S., Shadura, Yu.M. (2016). Use of cerium compounds in animal husbandry. State science and practice conf. "Agrarian science for production" (November 17, 2016, Bila Tserkva). pp. 84–85. (in Ukrainian)
- Bityutskyy, V.S., Tsekhmistrenko, O.S. (2017). Methods of obtaining nanocrystalline cerium dioxide and the use of its compounds. "Latest technologies of production and processing of animal husbandry products". State science and practice conf. of young scientists, graduate students and doctoral students, (May 18, 2017, Bila Tserkva). pp. 14–15. (in Ukrainian)
- Koshevoy, V.P., Onishchenko, O.V., Klochkov, V.K., Malyukin, Yu.V. (2015). Deficiency of colostral immunoglobulins in cows with mastodystrophy: prediction and screening methods. Veterinary Medicine of Ukraine, (3), pp. 17–22. (in Ukrainian).
- Spivak, M.Ya., Demchenko, O.A., Zholobak, N.M., Shcherbakov, O.B., Zotsenko, V.M., Ivanov, V.K. (2013). Effect of nanocrystalline ceriumdioxide on quail's egg productivity. Modern poultry farming, (3), pp. 22–24. (in Ukrainian)
- Spivak, M.Ya., Oksamitny, V.M., Demchenko, O.A., Zholobak, N.M., Shcherbakov, O.B., Ivanov, V.K., Grynevych, OH. (2013). The influence of ceriumdioxide nanoparticles on the intensity of growth and feed con sumption of young quails. Veterinary Medicine, (97), pp. 470–472. (in Ukrainian).
- Tsekhmistrenko, O.S., Tsekhmistrenko, S.I., Bityutskyy, V.S., Melnychenko, O.M., Oleshko, O.A. (2018). Biomimetic and antioxidant activity of nanocrystalline ceriumdioxide. World of medicine and biology, 1 (63), pp. 196–201. (in Ukrainian)
- Tsekhmistrenko, S.I., Bityutskyy, V.S., Tsekhmistrenko, O.S. (2021). Use of cerium compounds in agriculture. Theory, practice and science. Abstracts of XXIII International Scientific and Practical Conference. Tokyo, Japan, pp. 26–31. (in Ukrainian)
- Tsekhmistrenko, S.I., Bityutskyy, V.S., Tsekhmistrenko, O.S., Demchenko, O.A., Tymoshok, N.O., Melnychenko, O.M. (2022). Ecological biotechnologies of "green" synthesis of nanoparticles of metals, metaloxides, metalloids and the iruse. 270 p. (in Ukrainian)
- Shably, V.Ya., Dolgov, V.A., Boykov, Y.I. (1983). Methodological recommendations for the use of Tetrahymenapyri form is infusoria for toxicological and biological assessment of agricultural products. Kyiv, 15 p. (in Ukrainian)
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