Nanoplastics Can Move Up the Food Chain from Plants to Insects to Fish
hubie writes:
The concern about plastic pollution has become widespread after it was realised that mismanaged plastics in the environment break down into smaller pieces known as microplastics and nanoplastics. It is likely that nanoplastics, due to their small size, can pass through physiological barriers and enter organisms.
Despite the growing body of evidence on the potential toxicity of nanoplastics to plants, invertebrates and vertebrates, our understanding of plastic transfer in food webs is limited. For instance, little is known about nanoplastics in soil ecosystems and their uptake by soil organisms, despite the fact that agricultural soil is potentially receiving nanoplastics from different sources such as atmospheric deposition, irrigation with wastewater, application of sewage sludge for agricultural purposes, and use of mulching film. [...]
Researchers at the University of Eastern Finland have developed a novel, metallic fingerprint-based technique to detect and measure nanoplastics in organisms and, in this new study, they applied it to a model food chain consisting of three trophic levels, i.e., lettuce as a primary producer, black soldier fly larvae as a primary consumer, and the insectivorous fish (roach) as a secondary consumer. The researchers used commonly found plastic waste in the environment, including polystyrene (PS) and polyvinyl chloride (PVC) nanoplastics.
Lettuce plants were exposed to nanoplastics for 14 days via contaminated soil, after which they were harvested and fed to insects (black soldier fly larvae, which are used as a source of proteins in many countries). After five days of feeding with lettuce, the insects were fed to the fish for five days.
Using scanning electron microscopy, the researchers analysed the dissected plants, larvae and fish. The images showed that nanoplastics were taken up by the roots of the plants and accumulate in the leaves. Then, nanoplastics were transferred from the contaminated lettuce to the insects. [...] When the fish fed on the contaminated insects, particles were detected in the gills, liver and intestine tissues of the fish, whereas no particles were found in the brain tissue.
Journal Reference:
Fazel Abdolahpur Monikh, Sille Holm, Raine Kortet, et al. Quantifying the trophic transfer of sub-micron plastics in an assembled food chain [open]. Nano Today, 46, 2022. DOI: 10.1016/j.nantod.2022.101611
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