1. Magnetite nanoparticles effects on adverse responses of aquatic and terrestrial animal models
- Author
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Georgios Gallios, Anastasia Dimitriadi, Dimitra Stamkopoulou, Martha Kaloyianni, Maria Ovezik, Georgia Kastrinaki, Dimitra Bobori, Ioannis Tsiaoussis, George Koumoundouros, and Konstantinos Feidantsis
- Subjects
Environmental Engineering ,Health, Toxicology and Mutagenesis ,Cyprinidae ,Metal Nanoparticles ,Terrestrial animal ,Environmental Chemistry ,Animals ,Magnetite Nanoparticles ,Waste Management and Disposal ,Ecosystem ,Zebrafish ,Prussian carp ,Pollutant ,biology ,Chemistry ,Aquatic ecosystem ,biology.organism_classification ,Pollution ,Environmental chemistry ,Toxicity ,Models, Animal ,Carassius ,Nanoparticles ,Terrestrial ecosystem ,Cornu aspersum ,Water Pollutants, Chemical - Abstract
Among pollutants, nanoparticles (NPs) consist a potential environmental hazard, as they could possibly harm the aquatic and terrestrial ecosystems while having unpredictable repercussions on human health. Since monitoring the impact of NPs on aquatic and terrestrial life is challenging, due to the differential sensitivities of organisms to a given nanomaterial, the present study examines magnetite nanoparticles' mediated toxicity in different animal models, representing distinctive environments (terrestrial and aquatic). Oxidative, proteolytic and genotoxic effects were evaluated on the hemocytes of the snail Cornu aspersum; in addition to those, apoptotic effects were measured in gills and liver of the zebrafish Danio rerio, and the prussian carp Carassius gibelio. All biochemical parameters studied increased significantly in animals after 8 days exposure to NPs. Inter-species and inter-tissues differences in responses were evident. Our results suggest a common toxicity response mechanism functioning in the tissues of the three animals studied that is triggered by magnetite NPs. The simultaneous use of these parameters could be established after further investigation as a reliable multi-parameter approach for biomonitoring of terrestrial and aquatic ecosystems against magnetite nanoparticles. Additionally, the results of our study could contribute to the design of studies for the production and rational utilization of nanoparticles.
- Published
- 2019