
<div class="publication-info">
	<h3>Attenuation of combined nickel(II) oxide and manganese(II, III) oxide nanoparticles’ adverse effects with a complex of bioprotectors / Minigalieva I.A., Katsnelson B.A., Privalova L.I., Sutunkova M.P., Gurvich V.B., Shur V.Y., Shishkina E.V., Valamina I.E., Makeyev O.H., Panov V.G., Varaksin A.N., Grigoryeva E.V., Meshtcheryakova E.Y. // International Journal of Molecular Sciences. - 2015. - V. 16, l. 9. - P. 22555-22583.</h3>
	<dl>
		<dt>ISSN:</dt><dd>16616596</dd>
		<dt>Type:</dt><dd>Article</dd>
				<dt>Abstract:</dt><dd>Stable suspensions of NiO and Mn<inf>3</inf>O<inf>4</inf> nanoparticles (NPs) with a mean (±s.d.) diameter of 16.7 ± 8.2 and 18.4 ± 5.4 nm, respectively, purposefully prepared by laser ablation of 99.99% pure nickel or manganese in de-ionized water, were repeatedly injected intraperitoneally (IP) to rats at a dose of 2.5 mg/kg 3 times a week up to 18 injections, either alone or in combination. A group of rats was injected with this combination with the background oral administration of a “bio-protective complex” (BPC) comprising pectin, vitamins A, C, E, glutamate, glycine, N-acetylcysteine, selenium, iodide and omega-3 PUFA, this composition having been chosen based on mechanistic considerations and previous experience. After the termination of injections, many functional and biochemical indices and histopathological features (with morphometric assessment) of the liver, spleen, kidneys and brain were evaluated for signs of toxicity. The Ni and Mn content of these organs was measured with the help of the atomic emission and electron paramagnetic resonance spectroscopies. We obtained blood leukocytes for performing the RAPD (Random Amplified Polymorphic DNA) test. Although both metallic NPs proved adversely bio-active in many respects considered in this study, Mn<inf>3</inf>O<inf>4</inf>-NPs were somewhat more noxious than NiO-NPs as concerns most of the non-specific toxicity manifestations and they induced more marked damage to neurons in the striatum and the hippocampus, which may be considered an experimental correlate of the manganese-induced Parkinsonism. The comparative solubility of the Mn<inf>3</inf>O<inf>4</inf>-NPs and NiO-NPs in a biological medium is discussed as one of the factors underlying the difference in their toxicokinetics and toxicities. The BPC has attenuated both the organ-systemic toxicity and the genotoxicity of Mn<inf>3</inf>O<inf>4</inf>-NPs in combination with NiO-NPs. © 2015 by the authors; licensee MDPI, Basel, Switzerland.</dd>
		<dt>Author keywords:</dt><dd>Bioprotectors; Manganese(II, III) oxide; Nanoparticles; Nickel(II) oxide; Subchronic toxicity</dd>
		<dt>Index keywords:</dt><dd>acetylcysteine; alpha tocopherol; ascorbic acid; fish oil; glutamate sodium; glycine; manganese oxide nanoparticle; metal nanoparticle; nickel oxide nanoparticle; pectin; potassium iodide; protective </dd>
		<dt>DOI:</dt><dd>10.3390/ijms160922555</dd>
		<dt>Смотреть в Scopus:</dt>
			<dd>
								<a href="https://www.scopus.com/inward/record.uri?eid=2-s2.0-84941909923&doi=10.3390%2fijms160922555&partnerID=40&md5=86ef738cbc1c4b4a5d3253f3c4c8b9dd" target="_blank">https://www.scopus.com/inward/record.uri?eid=2-s2.0-84941909923&amp;doi=10.3390%2fijms160922555&amp;partnerID=40&amp;md5=86ef738cbc1c4b4a5d3253f3c4c8b9dd</a>
							</dd>

		<dt>Соавторы в МНС:</dt>
		<dd>
		&mdash;		</dd>

				<dt>Другие поля</dt>
		<dd>
			<table class="v-table">
			<thead>
				<tr>
					<td class="w8 gar">Поле</td>
					<td>Значение</td>
				</tr>
			</thead>
			<tbody>
								<tr>
						<td class="gar">Link</td>
						<td>https://www.scopus.com/inward/record.uri?eid=2-s2.0-84941909923&doi=10.3390%2fijms160922555&partnerID=40&md5=86ef738cbc1c4b4a5d3253f3c4c8b9dd</td>
					</tr>
										<tr>
						<td class="gar">Affiliations</td>
						<td>The Medical Research Center for Prophylaxis and Health Protection in Industrial Workers, 30 Popov Str, Ekaterinburg, Russian Federation; The Institute of Natural Sciences, The Ural Federal University, Ekaterinburg, Russian Federation; The Central Research Laboratory, The Ural State Medical University, 17 Klyuchevskaya Str, Ekaterinburg, Russian Federation; Institute of Industrial Ecology, The Urals Branch of the Russian Academy of Sciences, 20 Sofia Kovalevskaya Str, Ekaterinburg, Russian Federation</td>
					</tr>
										<tr>
						<td class="gar">Author Keywords</td>
						<td>Bioprotectors; Manganese(II, III) oxide; Nanoparticles; Nickel(II) oxide; Subchronic toxicity</td>
					</tr>
										<tr>
						<td class="gar">Chemicals/CAS</td>
						<td>acetylcysteine, 616-91-1; alpha tocopherol, 1406-18-4, 1406-70-8, 52225-20-4, 58-95-7, 59-02-9; ascorbic acid, 134-03-2, 15421-15-5, 50-81-7; fish oil, 8016-13-5; glutamate sodium, 142-47-2, 16177-21-2, 16690-92-9; glycine, 56-40-6, 6000-43-7, 6000-44-8; pectin, 9000-69-5; potassium iodide, 7681-11-0; selenium, 7782-49-2; iodide, 20461-54-5; manganese oxide, 11129-60-5, 1317-35-7; nickel, 7440-02-0; oxide, 16833-27-5; Acetylcysteine; Fatty Acids, Omega-3; Glycine; Iodides; Manganese Compounds; manganese oxide; Nickel; nickel monoxide; Oxides; pectin; Pectins; Protective Agents; Selenium; Vitamins</td>
					</tr>
										<tr>
						<td class="gar">References</td>
						<td>Katsnelson, B.A., Privalova, L.I., Degtyareva, T.D., Sutunkova, M.P., Experimental estimates of the toxicity of iron oxide Fe<inf>3</inf>O<inf>4</inf> (magnetite) nanoparticles (2010) Cent. Eur. J. Occup. Environ. Med, 16, pp. 47-63; Katsnelson, B.A., Degtyareva, T.D., Minigalieva, I.A., Privalova, L.I., Kuzmin, S.V., Yeremenko, O.S., Sub-chronic systemic toxicity and bio-accumulation of Fe3O4 nano-and microparticles following repeated intraperitoneal administration to rats (2011) Int. J. Toxicol, 30, pp. 60-67; Katsnelson, B.A., Privalova, L.I., Sutunkova, M.P., Gurvich, V.B., Loginova, N.V., Minigalieva, I.A., Kireyeva, E.P., Beikin, Y.B., Some inferences from in vivo experiments with metal and metal oxide nanoparticles: The pulmonary phagocytosis response, subchronic systemic toxicity and genotoxicity, regulatory proposals, searching for bioprotectors (a self-overview) (2015) Int. J. Nanomed, 10, pp. 3013-3029; Privalova, L.I., Katsnelson, B.A., Loginova, N.V., Gurvich, V.B., Shur, V.Y., Valamina, I.E., Subchronic toxicity of copper oxide nanoparticles and its attenuation with the help of a combination of bioprotectors (2014) Int. J. Mol. Sci, 15, pp. 12379-12406; Fröhlich, E., Cellular targets and mechanisms in the cytotoxic action of non-biodegradable engineered nanoparticles (2013) J. Curr. Drug Metab, 14, pp. 976-988; Katsnelson, B.A., Privalova, L.I., Gurvich, V.B., Makeyev, O.H., Shur, V.Y., Beikin, J.B., Sutunkova, M.P., Loginova, N.V., Comparative in vivo assessment of some adverse bio-effects of equidimensional gold and silver nanoparticles and the attenuation of nanosilver's effects with a complex of innocuous bioprotectors (2013) Int. J. Mol. Sci, 14, pp. 2449-2483; High-strength nickel-containing stainless steels are produced on a large scale and are extensively used in electric arc welding. Manganese steel may be produced in the same foundry. Manganese can also be an important component of both welded metal and welding electrode's coating; Keane, M., Stone, S., Chen, B., Welding fumes from stainless steel gas metal arc processes contain multiple manganese chemical species (2010) J. Environ. Monit, 12, pp. 1130-1140; Taube, F., Manganese in occupational arc welding fumes-Aspects on physiochemical properties, with focus on solubility (2012) Ann. Occup. Hyg, 57, pp. 6-25; Andujar, P., Simon-Deckers, A., Galateau-Salle, F., Fayard, B., Beaune, G., Clin, B., Billon-Galland, M.-A., Doucet, J., Role of metal oxide nanoparticles in histopathological changes observed in the lung of welders (2014) Part. Fibre Toxicol, 11, p. 23; Zhang, Q., Yukinori, K., Sato, K., Nakakuki, K., Koyahama, N., Donaldson, K., Differences in the extent of inflammation caused by intratracheal exposure to three ultrafine metals: Role of free radicals (1998) J. Toxicol. Environ. Health, 53, pp. 423-438; Zhang, Q., Yukinori, K., Zhu, X., Sato, K., Mo, Y., Kluz, T., Domaldson, K., Comparative toxicity of standard nickel and ultrafine nickel after intratracheal instillation (2003) J. Occup. Health, 45, pp. 23-30; Magaye, R., Zhao, J., Recent progress in studies of metallic nickel and nickel-based nanoparticles' genotoxicity and carcinogenicity (2012) Environ. Toxicol. Pharmacol, 34, pp. 644-650; Morimoto, Y., Hirohashi, M., Ogami, A., Oyabu, T., Myojo, T., Hashiba, M., Pulmonary toxicity following an intratracheal instillation of nickel oxide nanoparticle agglomerates (2011) J. Occup. Health, 53, pp. 293-295; Capasso, L., Camatini, M., Gualtieri, M., Nickel oxide nanoparticles induce inflammation and genotoxic effect in lung epithelial cells (2014) Toxicol. Lett, 226, pp. 28-34; Saber, M., Hussain, S.M., Javorina, A.K., Schrand, A.M., Duhart, H.M., The Interaction of Manganese Nanoparticles with PC-12 Cells Induces Dopamine Depletion (2006) Toxicol. Sci, 92, pp. 456-463; Singh, S.P., Kumari, M., Kumari, S.I., Rahman, M.F., Mahboob, M., Grover, P., Toxicity assessment of manganese oxide micro and nanoparticles in Wistar rats after 28 days of repeated oral exposure (2013) J. Appl. Toxicol, 33, pp. 1165-1179; Bellusci, M., La Barbera, A., Padella, F., Mancuso, M., Pasquo, A., Grollino, M.G., Biodistribution and acute toxicity of a nanofluid containing manganese iron oxide nanoparticles produced by a mechanochemical process (2014) Int. J. Nanomed, 9, pp. 1919-1929; Manganese. Environmental Health Criteria 17. IPCS International Programme on Chemical Safety; WHO: Geneva, Switzerland, 1981; Nickel. Environmental Health Criteria 108. IPCS International Programme on Chemical Safety; WHO: Geneva, Switzerland, 1991; Chromium, Nickel and Welding (1990) IARC Monographs on the Evaluation of Carcinogenic Risks to Humans, 49, pp. 1-677. , IARC: Lyon, France; Katsnelson, B.A., Panov, V.G., Minigaliyeva, I.A., Varaksin, A.N., Privalova, L.I., Slyshkina, T.V., Grebenkina, S.V., Further development of the theory and mathematical description of combined toxicity: An approach to classifying types of action of three-factorial combinations (a case study of manganese-chromium-nickel subchronic intoxication) (2015) Toxicology, 334, pp. 33-34; Katsnelson, B.A., Kuzmin, S.V., Degtyareva, T.D., Privalova, L.I., Soloboyeva, J.I., "Biological prophylaxis"-One of the ways to proceed from the analytical environmental epidemiology to the population health protection (2008) Cent. Eur. J. Occup. Environ. Med, 14, pp. 41-42; Katsnelson, B.A., Privalova, L.I., Gurvich, V.B., Kuzmin, S.V., Kireyeva, E.P., Minigalieva, I.A., Enhancing population's resistance to toxic exposures as an auxilliary tool of decreasing environmental and occupational health risks (a self-overview) (2014) J. Environ. Prot, 5, pp. 1435-1449; Katsnelson, B.A., Minigalieva, I.A., Privalova, L.I., Sutunkova, M.P., Gurvich, V.B., Shur, V.B., Lower airways response in rats to a single or combined intratracheal instillation of manganese and nickel nanoparticles and its attenuation with a bio-protective pre-treatment (2014) Toksicol. Vestnik, 6, pp. 8-14; Geiser, M., Kreyling, W.G., Deposition and biokinetics of inhaled nanoparticles (2010) Part. Fibre Toxicol, 7, p. 2; Human Respiratory Tract Model for Radiological Protection., A report of a Task Group of the International Commission on Radiological Protection (1994) Ann. ICRP, 24, pp. 1-482; Kreyling, W.G., Geiser, M., Dosimetry of inhaled nanoparticles (2009) Nanoparticles in Medicine and Environment, Inhalation and Health Effects, pp. 145-173. , Marijnissen, J.C., Gradon, L., Eds.; Springer: Berlin, Germany; Fröhlich, E., Salar-Behzadi, S., Toxicological assessment of inhaled nanoparticles: Role of in vivo, ex vivo, in vitro, and in silico studies (2014) Int. J. Mol. Sci, 15, pp. 4795-4822; Sadauskas, E., Wallin, H., Stolenberg, M., Vogel, U., Doering, P., Larsen, A., Kupffer cells are central in the removal of nanoparticles from the organism (2007) Part. Fibre Toxicol, 4, pp. 10-16; Lasagna-Reeves, C., Gonzalez-Romero, D., Barria, M.A., Olmedo, I., Clos, A., Sadagopa Ramanujam, V.M., Bioaccumulation and toxicity of gold nanoparticles after repeated administration in mice (2010) Biochem. Biophys. Res. Commun, 393, pp. 649-655; AST, bilirubin, uric acid, thyrotropic hormone, SH-groups in the blood serum, monocyte and thrombocyte counts; Glantzounis, G.K., Tsimoyiannis, E.C., Kappas, A.M., Galaris, D.A., Uric acid and oxidative stress (2005) Curr. Pharm. Des, 11, pp. 4145-4151; Desole, M.S., Miele, M., Esposito, G., Mighell, R., Fresu, L., de Matale, G., Miele, E., Dopaminergic system activity and cellular defense mechanisms in the striatum and striatal synaptosomes of the rat subchronically exposed to manganese (1994) Arch. Toxicol, 68, pp. 566-570; Sun, X.M., Liu, Y.W., Wang, Z.Q., Li, H.B., Liu, Y., Di, D.L., Effect of occupational manganese exposure on uric acid levels in human urine (2011) BioMed Environ. Sci, 24, pp. 222-227; Gaforio, J.J., Serrano, M.J., Algarra, I., Ortega, E., Alvarez de Cienfuegos, G., Phagocytosis of apoptotic cells assessed by flow cytometry using 7-aminoactinomycin D (2002) Cytometry, 49, pp. 8-11; Canbay, A., Feldstein, A.E., Higuchi, H., Werneburg, N., Grambihler, A., Bronk, S.F., Gores, G.J., Kupffer cell engulfment of apoptotic bodies stimulates death ligand and cytokine expression (2003) Hepatology, 38, pp. 1188-1198; Manke, A., Wang, L., Rojanasakul, Y., Mechanisms of nanoparticle-induced oxidative stress and toxicity (2013) BioMed Res. Int, 2013, p. 942916; Tkeshelashvili, L.K., Tsakadze, K.J., Khulusauri, O.V., Effect of some nickel compounds on erythrocyte characteristics (1989) Biol. Trace Elem. Res, 21, pp. 337-342; Tietz, N.W., (1995) Clinical Guide to Laboratory Tests, 3rd ed, p. 942. , W.B. Saunders Company: Philadelphia, PA, USA; We did not perform morphometric measurements in rats administered the BPC without NPs IP exposures because microscopic picture of the organs in those rats was clearly normal not differing from that in controls; Katsnelson, B.A., Makeyev, O.H., Kochneva, N.I., Privalova, L.I., Degtyareva, T.D., Bukhantsev, V.A., Minin, V.V., Kostyukova, S.V., Testing a set of bioprotectors against the genotoxic effect of a combination of ecotoxicants (2007) Cent. Eur. J. Occup. Environ. Med, 13, pp. 251-264; Morosova, K.I., Aronova, G.V., Katsnelson, B.A., Velichkovski, B.T., Genkin, A.M., Elnichnykh, L.N., Privalova, L.I., On the defensive action of glutamate on the cytotoxicity and fibrogenicity of quartz dust (1982) Br. J. Ind. Med, 39, pp. 244-252; Privalova, L.I., Katsnelson, B.A., Sutunkova, M.P., Valamina, I.E., Beresneva, O.Y., Degtyareva, T.D., Yeremenko, O.S., Attenuation of some adverse health effects of chrysotile asbestos with a bioprotective complex in animal experiments (2007) Cent. Eur. J. Occup. Environ. Med, 13, pp. 265-276; Katsnelson, B.A., Yeremenko, O.S., Privalova, L.I., Makeyev, O.H., Degtyareva, T.D., Beresneva, O.Y., Valamina, I.E., Kireyeva, E.P., Toxicity of monazite particulate and its attenuation with a complex of bio-protectors (2009) Med. Lavoro, 100, pp. 455-470; Karki, P., Lee, E., Aschner, M., Manganese Neurotoxicity: A Focus on Glutamate Transporters (2013) Ann. Occup. Environ. Med, 25, p. 4; Sidoryk-Wegrzynowicz, M., Aschner, M., Role of astrocytes in manganese mediated (2013) BMC Pharmacol. Toxicol, 14, p. 23; Desole, M.S., Esposito, G., Migheli, R., Sircana, S., Delogu, M.R., Fresu, L., Miele, M., Miele, E., Glutathione deficiency potentiates manganese toxicity in rat striatum and brainstem and in PC12 cells (1997) Pharmacol. Res, 36, pp. 285-292; Soldin, O.P., Aschner, M., Effects of manganese on thyroid hormone homeostasis: Potential links (2007) Neurotoxicology, 28, pp. 951-956</td>
					</tr>
										<tr>
						<td class="gar">Correspondence Address</td>
						<td>Katsnelson, B.A.; The Medical Research Center for Prophylaxis and Health Protection in Industrial Workers, 30 Popov Str, Russian Federation</td>
					</tr>
										<tr>
						<td class="gar">Publisher</td>
						<td>MDPI AG</td>
					</tr>
										<tr>
						<td class="gar">PubMed ID</td>
						<td>26393577</td>
					</tr>
										<tr>
						<td class="gar">Language of Original Document</td>
						<td>English</td>
					</tr>
										<tr>
						<td class="gar">Abbreviated Source Title</td>
						<td>Int. J. Mol. Sci.</td>
					</tr>
										<tr>
						<td class="gar">Source</td>
						<td>Scopus</td>
					</tr>
								</tbody>
			</table>
		</dd>
			</dl>

</div>
Поле	Значение
Link	https://www.scopus.com/inward/record.uri?eid=2-s2.0-84941909923&doi=10.3390%2fijms160922555&partnerID=40&md5=86ef738cbc1c4b4a5d3253f3c4c8b9dd
Affiliations	The Medical Research Center for Prophylaxis and Health Protection in Industrial Workers, 30 Popov Str, Ekaterinburg, Russian Federation; The Institute of Natural Sciences, The Ural Federal University, Ekaterinburg, Russian Federation; The Central Research Laboratory, The Ural State Medical University, 17 Klyuchevskaya Str, Ekaterinburg, Russian Federation; Institute of Industrial Ecology, The Urals Branch of the Russian Academy of Sciences, 20 Sofia Kovalevskaya Str, Ekaterinburg, Russian Federation
Author Keywords	Bioprotectors; Manganese(II, III) oxide; Nanoparticles; Nickel(II) oxide; Subchronic toxicity
Chemicals/CAS	acetylcysteine, 616-91-1; alpha tocopherol, 1406-18-4, 1406-70-8, 52225-20-4, 58-95-7, 59-02-9; ascorbic acid, 134-03-2, 15421-15-5, 50-81-7; fish oil, 8016-13-5; glutamate sodium, 142-47-2, 16177-21-2, 16690-92-9; glycine, 56-40-6, 6000-43-7, 6000-44-8; pectin, 9000-69-5; potassium iodide, 7681-11-0; selenium, 7782-49-2; iodide, 20461-54-5; manganese oxide, 11129-60-5, 1317-35-7; nickel, 7440-02-0; oxide, 16833-27-5; Acetylcysteine; Fatty Acids, Omega-3; Glycine; Iodides; Manganese Compounds; manganese oxide; Nickel; nickel monoxide; Oxides; pectin; Pectins; Protective Agents; Selenium; Vitamins
References	Katsnelson, B.A., Privalova, L.I., Degtyareva, T.D., Sutunkova, M.P., Experimental estimates of the toxicity of iron oxide Fe3O4 (magnetite) nanoparticles (2010) Cent. Eur. J. Occup. Environ. Med, 16, pp. 47-63; Katsnelson, B.A., Degtyareva, T.D., Minigalieva, I.A., Privalova, L.I., Kuzmin, S.V., Yeremenko, O.S., Sub-chronic systemic toxicity and bio-accumulation of Fe3O4 nano-and microparticles following repeated intraperitoneal administration to rats (2011) Int. J. Toxicol, 30, pp. 60-67; Katsnelson, B.A., Privalova, L.I., Sutunkova, M.P., Gurvich, V.B., Loginova, N.V., Minigalieva, I.A., Kireyeva, E.P., Beikin, Y.B., Some inferences from in vivo experiments with metal and metal oxide nanoparticles: The pulmonary phagocytosis response, subchronic systemic toxicity and genotoxicity, regulatory proposals, searching for bioprotectors (a self-overview) (2015) Int. J. Nanomed, 10, pp. 3013-3029; Privalova, L.I., Katsnelson, B.A., Loginova, N.V., Gurvich, V.B., Shur, V.Y., Valamina, I.E., Subchronic toxicity of copper oxide nanoparticles and its attenuation with the help of a combination of bioprotectors (2014) Int. J. Mol. Sci, 15, pp. 12379-12406; Fröhlich, E., Cellular targets and mechanisms in the cytotoxic action of non-biodegradable engineered nanoparticles (2013) J. Curr. Drug Metab, 14, pp. 976-988; Katsnelson, B.A., Privalova, L.I., Gurvich, V.B., Makeyev, O.H., Shur, V.Y., Beikin, J.B., Sutunkova, M.P., Loginova, N.V., Comparative in vivo assessment of some adverse bio-effects of equidimensional gold and silver nanoparticles and the attenuation of nanosilver's effects with a complex of innocuous bioprotectors (2013) Int. J. Mol. Sci, 14, pp. 2449-2483; High-strength nickel-containing stainless steels are produced on a large scale and are extensively used in electric arc welding. Manganese steel may be produced in the same foundry. Manganese can also be an important component of both welded metal and welding electrode's coating; Keane, M., Stone, S., Chen, B., Welding fumes from stainless steel gas metal arc processes contain multiple manganese chemical species (2010) J. Environ. Monit, 12, pp. 1130-1140; Taube, F., Manganese in occupational arc welding fumes-Aspects on physiochemical properties, with focus on solubility (2012) Ann. Occup. Hyg, 57, pp. 6-25; Andujar, P., Simon-Deckers, A., Galateau-Salle, F., Fayard, B., Beaune, G., Clin, B., Billon-Galland, M.-A., Doucet, J., Role of metal oxide nanoparticles in histopathological changes observed in the lung of welders (2014) Part. Fibre Toxicol, 11, p. 23; Zhang, Q., Yukinori, K., Sato, K., Nakakuki, K., Koyahama, N., Donaldson, K., Differences in the extent of inflammation caused by intratracheal exposure to three ultrafine metals: Role of free radicals (1998) J. Toxicol. Environ. Health, 53, pp. 423-438; Zhang, Q., Yukinori, K., Zhu, X., Sato, K., Mo, Y., Kluz, T., Domaldson, K., Comparative toxicity of standard nickel and ultrafine nickel after intratracheal instillation (2003) J. Occup. Health, 45, pp. 23-30; Magaye, R., Zhao, J., Recent progress in studies of metallic nickel and nickel-based nanoparticles' genotoxicity and carcinogenicity (2012) Environ. Toxicol. Pharmacol, 34, pp. 644-650; Morimoto, Y., Hirohashi, M., Ogami, A., Oyabu, T., Myojo, T., Hashiba, M., Pulmonary toxicity following an intratracheal instillation of nickel oxide nanoparticle agglomerates (2011) J. Occup. Health, 53, pp. 293-295; Capasso, L., Camatini, M., Gualtieri, M., Nickel oxide nanoparticles induce inflammation and genotoxic effect in lung epithelial cells (2014) Toxicol. Lett, 226, pp. 28-34; Saber, M., Hussain, S.M., Javorina, A.K., Schrand, A.M., Duhart, H.M., The Interaction of Manganese Nanoparticles with PC-12 Cells Induces Dopamine Depletion (2006) Toxicol. Sci, 92, pp. 456-463; Singh, S.P., Kumari, M., Kumari, S.I., Rahman, M.F., Mahboob, M., Grover, P., Toxicity assessment of manganese oxide micro and nanoparticles in Wistar rats after 28 days of repeated oral exposure (2013) J. Appl. Toxicol, 33, pp. 1165-1179; Bellusci, M., La Barbera, A., Padella, F., Mancuso, M., Pasquo, A., Grollino, M.G., Biodistribution and acute toxicity of a nanofluid containing manganese iron oxide nanoparticles produced by a mechanochemical process (2014) Int. J. Nanomed, 9, pp. 1919-1929; Manganese. Environmental Health Criteria 17. IPCS International Programme on Chemical Safety; WHO: Geneva, Switzerland, 1981; Nickel. Environmental Health Criteria 108. IPCS International Programme on Chemical Safety; WHO: Geneva, Switzerland, 1991; Chromium, Nickel and Welding (1990) IARC Monographs on the Evaluation of Carcinogenic Risks to Humans, 49, pp. 1-677. , IARC: Lyon, France; Katsnelson, B.A., Panov, V.G., Minigaliyeva, I.A., Varaksin, A.N., Privalova, L.I., Slyshkina, T.V., Grebenkina, S.V., Further development of the theory and mathematical description of combined toxicity: An approach to classifying types of action of three-factorial combinations (a case study of manganese-chromium-nickel subchronic intoxication) (2015) Toxicology, 334, pp. 33-34; Katsnelson, B.A., Kuzmin, S.V., Degtyareva, T.D., Privalova, L.I., Soloboyeva, J.I., "Biological prophylaxis"-One of the ways to proceed from the analytical environmental epidemiology to the population health protection (2008) Cent. Eur. J. Occup. Environ. Med, 14, pp. 41-42; Katsnelson, B.A., Privalova, L.I., Gurvich, V.B., Kuzmin, S.V., Kireyeva, E.P., Minigalieva, I.A., Enhancing population's resistance to toxic exposures as an auxilliary tool of decreasing environmental and occupational health risks (a self-overview) (2014) J. Environ. Prot, 5, pp. 1435-1449; Katsnelson, B.A., Minigalieva, I.A., Privalova, L.I., Sutunkova, M.P., Gurvich, V.B., Shur, V.B., Lower airways response in rats to a single or combined intratracheal instillation of manganese and nickel nanoparticles and its attenuation with a bio-protective pre-treatment (2014) Toksicol. Vestnik, 6, pp. 8-14; Geiser, M., Kreyling, W.G., Deposition and biokinetics of inhaled nanoparticles (2010) Part. Fibre Toxicol, 7, p. 2; Human Respiratory Tract Model for Radiological Protection., A report of a Task Group of the International Commission on Radiological Protection (1994) Ann. ICRP, 24, pp. 1-482; Kreyling, W.G., Geiser, M., Dosimetry of inhaled nanoparticles (2009) Nanoparticles in Medicine and Environment, Inhalation and Health Effects, pp. 145-173. , Marijnissen, J.C., Gradon, L., Eds.; Springer: Berlin, Germany; Fröhlich, E., Salar-Behzadi, S., Toxicological assessment of inhaled nanoparticles: Role of in vivo, ex vivo, in vitro, and in silico studies (2014) Int. J. Mol. Sci, 15, pp. 4795-4822; Sadauskas, E., Wallin, H., Stolenberg, M., Vogel, U., Doering, P., Larsen, A., Kupffer cells are central in the removal of nanoparticles from the organism (2007) Part. Fibre Toxicol, 4, pp. 10-16; Lasagna-Reeves, C., Gonzalez-Romero, D., Barria, M.A., Olmedo, I., Clos, A., Sadagopa Ramanujam, V.M., Bioaccumulation and toxicity of gold nanoparticles after repeated administration in mice (2010) Biochem. Biophys. Res. Commun, 393, pp. 649-655; AST, bilirubin, uric acid, thyrotropic hormone, SH-groups in the blood serum, monocyte and thrombocyte counts; Glantzounis, G.K., Tsimoyiannis, E.C., Kappas, A.M., Galaris, D.A., Uric acid and oxidative stress (2005) Curr. Pharm. Des, 11, pp. 4145-4151; Desole, M.S., Miele, M., Esposito, G., Mighell, R., Fresu, L., de Matale, G., Miele, E., Dopaminergic system activity and cellular defense mechanisms in the striatum and striatal synaptosomes of the rat subchronically exposed to manganese (1994) Arch. Toxicol, 68, pp. 566-570; Sun, X.M., Liu, Y.W., Wang, Z.Q., Li, H.B., Liu, Y., Di, D.L., Effect of occupational manganese exposure on uric acid levels in human urine (2011) BioMed Environ. Sci, 24, pp. 222-227; Gaforio, J.J., Serrano, M.J., Algarra, I., Ortega, E., Alvarez de Cienfuegos, G., Phagocytosis of apoptotic cells assessed by flow cytometry using 7-aminoactinomycin D (2002) Cytometry, 49, pp. 8-11; Canbay, A., Feldstein, A.E., Higuchi, H., Werneburg, N., Grambihler, A., Bronk, S.F., Gores, G.J., Kupffer cell engulfment of apoptotic bodies stimulates death ligand and cytokine expression (2003) Hepatology, 38, pp. 1188-1198; Manke, A., Wang, L., Rojanasakul, Y., Mechanisms of nanoparticle-induced oxidative stress and toxicity (2013) BioMed Res. Int, 2013, p. 942916; Tkeshelashvili, L.K., Tsakadze, K.J., Khulusauri, O.V., Effect of some nickel compounds on erythrocyte characteristics (1989) Biol. Trace Elem. Res, 21, pp. 337-342; Tietz, N.W., (1995) Clinical Guide to Laboratory Tests, 3rd ed, p. 942. , W.B. Saunders Company: Philadelphia, PA, USA; We did not perform morphometric measurements in rats administered the BPC without NPs IP exposures because microscopic picture of the organs in those rats was clearly normal not differing from that in controls; Katsnelson, B.A., Makeyev, O.H., Kochneva, N.I., Privalova, L.I., Degtyareva, T.D., Bukhantsev, V.A., Minin, V.V., Kostyukova, S.V., Testing a set of bioprotectors against the genotoxic effect of a combination of ecotoxicants (2007) Cent. Eur. J. Occup. Environ. Med, 13, pp. 251-264; Morosova, K.I., Aronova, G.V., Katsnelson, B.A., Velichkovski, B.T., Genkin, A.M., Elnichnykh, L.N., Privalova, L.I., On the defensive action of glutamate on the cytotoxicity and fibrogenicity of quartz dust (1982) Br. J. Ind. Med, 39, pp. 244-252; Privalova, L.I., Katsnelson, B.A., Sutunkova, M.P., Valamina, I.E., Beresneva, O.Y., Degtyareva, T.D., Yeremenko, O.S., Attenuation of some adverse health effects of chrysotile asbestos with a bioprotective complex in animal experiments (2007) Cent. Eur. J. Occup. Environ. Med, 13, pp. 265-276; Katsnelson, B.A., Yeremenko, O.S., Privalova, L.I., Makeyev, O.H., Degtyareva, T.D., Beresneva, O.Y., Valamina, I.E., Kireyeva, E.P., Toxicity of monazite particulate and its attenuation with a complex of bio-protectors (2009) Med. Lavoro, 100, pp. 455-470; Karki, P., Lee, E., Aschner, M., Manganese Neurotoxicity: A Focus on Glutamate Transporters (2013) Ann. Occup. Environ. Med, 25, p. 4; Sidoryk-Wegrzynowicz, M., Aschner, M., Role of astrocytes in manganese mediated (2013) BMC Pharmacol. Toxicol, 14, p. 23; Desole, M.S., Esposito, G., Migheli, R., Sircana, S., Delogu, M.R., Fresu, L., Miele, M., Miele, E., Glutathione deficiency potentiates manganese toxicity in rat striatum and brainstem and in PC12 cells (1997) Pharmacol. Res, 36, pp. 285-292; Soldin, O.P., Aschner, M., Effects of manganese on thyroid hormone homeostasis: Potential links (2007) Neurotoxicology, 28, pp. 951-956
Correspondence Address	Katsnelson, B.A.; The Medical Research Center for Prophylaxis and Health Protection in Industrial Workers, 30 Popov Str, Russian Federation
Publisher	MDPI AG
PubMed ID	26393577
Language of Original Document	English
Abbreviated Source Title	Int. J. Mol. Sci.
Source	Scopus