Ecotoxicidad de nanopartículas metálicas y superparamagnéticas de óxido de hierro en dos especies
Abstract
Introducción: la nanotecnología y el empleo de materiales a nano escala son un área relativamente nueva de la ciencia y la tecnología con un gran crecimiento en el mercado global. Muchos de los productos no cuentan con estudios que garanticen su uso seguro, tanto para el hombre como para los ecosistemas. Los estudios ecotoxicológicos permiten evaluar los efectos de un determinado xenobiótico sobre especies representativas de los diferentes compartimentos ambientales.Objetivo: evaluar los efectos tóxicos de nanopartículas de Ag, Au, Ag/Ag y superparamagnéticas de óxido de hierro, en dos especies bioindicadoras de los ecosistemas terrestre y acuático.
Métodos: como parte de los estudios de seguridad se realizaron ensayos de toxicidad aguda por contacto en lombriz de tierra de la especie Eisenia andrei, con una duración de 96 horas y estudios en anfibios de la especie Osteopillus septentrionales en diferentes etapas del desarrollo (embrionario y larval). Se evaluó la ocurrencia de mortalidad y de efectos tóxicos, en el caso del ensayo en lombriz de tierra; se determinó además la viabilidad celular.
Resultados: los efectos tóxicos más significativos en el caso de la lombriz de tierra fueron, la ocurrencia de alteraciones fisiológicas y conductuales al ser expuesta a NPs de Ag de 3 nm y superparamagnéticas de óxido de hierro, estas últimas provocaron citotoxicidad a la concentración 1,38 mg/mL. En el caso de los anfibios se evidenció toxicidad en NPs de Ag 3 nm y superparamagnéticas de óxido de hierro.
Conclusiones: todas las nanopartículas mostraron efectos tóxicos en las especies bioindicadoras evaluadas.
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References
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3. Caballero Díaz E. Nanopartículas como herramientas analíticas y estudios toxicológicos asociados. [Tesis] Córdoba (España): Universidad de Córdoba; 2014. [citado 8 may 2017]. Disponible en: http://helvia.uco.es/xmlui/handle/10396/11958
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5. Zhao X,Liu R. Recent progress and perspectives on the toxicity of carbon nanotubes at organism, organ, cell and biomacromolecule levels. Environ Int. 2012;40:244-55.
6. Parveen S, Misra R, Sahoo SK. Nanoparticles: a boon to drug delivery, therapeutics, diagnostics and imaging. Nanomed-Nanotechnol. 2012;8:147-66.
7. Cuevas MC, Solís FA, Martínez A. Monitoreo de suelos contaminados mediante pruebas ecotoxicológicas. Tlatemoani. 2012;(11):1-10.
8. Organisation for Economic Co-operation and Development. Earthworm, acute toxicity test. OECD 207. Washington: Organisation for Economic Cooperation and Development; 1984.
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12. Rizzo LY, Golombek SK, Mertens ME, Pan Y, Laaf D, Broda J, et al. In vivo nanotoxicity testing using the Zebrafish embryo assay. Journal of Materials Chemistry B. 2013;1(32):3918-25.
13. Mattsson K, Ekvall MT, Hansson LA, Linse S, Malmendal A, Cedervall T. Altered behavior, physiology, and metabolism in fish exposed to polystyrene nanoparticles. Environ Sci Technol. 2014;49(1):553-61.
14. Bar-Ilan O, Albrecht RM, Fako VE, Furgeso DY. Toxicity assessments of multisized gold and silver nanoparticles in zebrafish embryos. Small. 2009;5:1897-910.
15. German Environment Agency. Nanomaterials in the environment - current state of knowledge and regulations on chemical safety. Berlin: German Environment Agency; 2012.
16. Kus M, Gernjak W, Rodriguez SM, Icli SA. Comparative study of supported TiO2 as photocatalyst in water decontamination at solar pilot plant scale. J Solar Energy Engineering. 2006;128(3):331-7.
17. Schwirn K, Tietjen L, Beer I. Why are nanomaterials different and how can they be appropriately regulated under REACH?. Environ Sci Eur. 2014;26(1):4.
Published
2017-08-22
How to Cite
1.
Domínguez Linares Y, Beiro Castro O, Peláez Rodríguez R, Díaz García A, Lóriga Loaces E, Fraga Álvarez R. Ecotoxicidad de nanopartículas metálicas y superparamagnéticas de óxido de hierro en dos especies. Rev Cubana Med Milit [Internet]. 2017 Aug. 22 [cited 2025 Apr. 10];46(2). Available from: https://revmedmilitar.sld.cu/index.php/mil/article/view/31
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