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Nanoplastic Toxicity: Insights and Challenges from Experimental Model Systems
Summary
This review summarizes what researchers have learned about nanoplastic toxicity from studies in cell cultures, aquatic organisms, and terrestrial animals. Evidence indicates that nanoplastics can be internalized by cells through various mechanisms and their toxicity depends on factors like particle size, surface modifications, and concentration. The study identifies key knowledge gaps and recommends more systematic research to better understand the health risks these particles may pose to humans.
Nanoplastic particles (NPs) can be produced or derived from the degradation of several daily used products and can therefore be found in the air, water, and food. Every day, these microscopic particles are confronted by different routes of exposure. Recent investigations have shown the internalization of these particles, differing in size and modification, in vivo in aquatic organisms and terrestrial organisms, as well as in vitro in different human cell lines. During the last years, the number of studies investigating the effects of NPs using widely different model systems and experimental approaches is exponentially growing, thus providing information about NPs, especially about polystyrene particle toxicity on health. To facilitate the grasping of the most relevant information, an overview is provided on the toxic effects of NPs coming from studies in cellular systems and in vivo in model organisms and on aspects which can be of particular relevance for particle toxicity (e.g., particle internalization mechanisms and structural modifications). Major achievements and gaps in the field as well as the point of view on how more systematic studies and exploitation of in vivo model organisms may improve the knowledge on important aspects of NPs are also pointed out.
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