Biorremediación del bisfenol A (BPA) y su potencial para el mejoramiento de la calidad de cuerpos de agua afectados por este contaminante industrial

Autor: Sánchez-Aburto, Gilberto, Vargas-Castillo, Elizabeth, Yañez-Apam, Jimena, Zambrano-Carrasco, Josué, Carreño-López, Ricardo, Vázquez-Pineros, Mónica Andrea, Marín-Cevada, Vianey
Jazyk: Spanish; Castilian
Rok vydání: 2019
Předmět:
DOI: 10.5281/zenodo.5090480
Popis: RESUMEN El bisfenol A (BPA por sus siglas en inglés), un compuesto orgánico fenólico, fue sintetizado por primera vez en Alemania hace más de un siglo. Su auge industrial comenzó a mediados del siglo XX, en donde ¡nidalmente se combinaba con diferentes químicos para la producción de plásticos y resinas. Durante las últimas décadas, se ha reportado ampliamente sus efectos nocivos. En las salud humana, se han comprobado sus efectos genotóxicos, neurotóxicos, así como su efecto como disruptor endocrino. Adicionalmente, el BPA es un compuesto recalcitrante, encontrándose en agua, suelo y atmósfera en concentraciones perjudiciales para la fauna y flora residente de los sitios afectados, causando efectos irreversibles. El ecosistema acuático es particularmente vulnerable a la toxicidad por BPA. Este compuesto entra en los cuerpos de agua a través de los efluentes de plantas de tratamiento de aguas residuales y vertederos. Por lo anterior, es necesario desarrollar sistemas eficientes para la recuperación de los sistemas acuáticos afectados por BPA. Dentro de las herramientas más eficientes como alternativas para el tratamiento del BPA, se encuentra la bioremediación, debido al papel principal que cumplen los microorganismos para la transformación, degradación y eliminación del BPA. Así, en este artículo se presenta una pequeña revisión sobre los alcances y logros de la bioremediación del BPA, con énfasis en ambientes acuáticos. ABSTRACT The Bisphenol A (BPA), a phenolic organic compound, was synthetized more than a century ago, for the first time in Germany. BPA industrial boom began in the middle of the 20th century, where it was combined with different Chemicals for the production of resins and plástic. Over the last decades, harmful effects of BPA have been widely reported. On human health, it has been shown to have genotoxic and neurotoxic effects, as well as effects as an endocrine disruptor. In addition, BPA it is a recalcitrant compound, it is found in soils, water and in the atmosphere in harmful concentrations for the fauna and flora that inhabits the affected sites. The aquatic ecosystem is of particular vulnerability to BPA toxicity. BPA enters to water bodies through effluents from wastewater treatment plants and landfills. For these reasons, it is necessary to develop efficient systems for the recovery of the affected aquatic ecosystems by BPA. Among the most efficient tools as alternatives for BPA treatment, it is found the bioremediation, this is due to the mail role that microorganisms play for BPA transformation, degradation and elimination. Thus, this paper present an overview about the progress and achievements of BPA bioremediation with focus on aquatic environments.
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