Технологія виробництва і переробки продуктів тваринництва (May 2021)
Toxicity, biotransformation and bioaccumulation of silver nanoparticles in laboratory conditions and aquatic ecosystems
Abstract
Generalized studies of the world scientific literature on the fate and risk assessment of exposure to silver nanoparticles (NPAg) both at the ecosystem level and at the organism level, as well as in the laboratory. It is emphasized that the toxic effect of silver nanoparticles, mechanisms and methods of action of NPAg on the body of aquatic organisms have been sufficiently studied in laboratory practice. However, there are some gaps and discrepancies between the results of laboratory tests and the study of real environmental consequences, and such inconsistencies hinder the development of appropriate effective measures to achieve environmental well-being. To bridge such gaps, this review summarizes how environmental conditions and the physicochemical properties of NPAg influence conflicting conclusions between laboratory and real-world environmental studies. It is emphasized that modern research on the pathways of entry, transformation and bioaccumulation of silver nanoparticles in natural aquatic ecosystems emphasizes the ability of such nanoparticles to penetrate intact physiological barriers, which is extremely dangerous. It is proved that silver nanoparticles have a toxic effect on microorganisms, macrophytes and aquatic organisms. The toxic effects of NPAg cover almost entire aquatic ecosystems. A study by a number of authors on the factors influencing the mobility, bioavailability, toxicity and environmental fate of Ag nanoparticles was analyzed to assess the environmental risk. In addition, this review systematically examines the various toxic effects of silver nanoparticles in the environment and compares these effects with the results obtained in laboratory practice, which is useful for assessing the environmental effects of such compounds. The dangerous chronic effects of low-concentration NPAg (μg/l) on natural aquatic ecosystems over a long period of time (months to several years) have been described in detail. In addition, the prospects for future studies of NPAg toxicity in natural freshwater environments are emphasized.
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