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Rapid egestion of microplastics in juvenile barramundi: No evidence of gut retention or tissue translocation

Amanda L. Dawson, Marina Santana, Michelle A. Perez, Kristin Meehan, Hannah McCarthy, Keegan Vickers, Cherie A. Motti

2025Environmental Pollution13 citationsDOIOpen Access PDF

Abstract

Despite many reports of large microplastics being isolated from fish muscle, there are limited exposure studies documenting the transport of microplastics >10 μm from the gastrointestinal tract (GIT) to surrounding tissues. Moreover, egestion rates of microplastics are not commonly studied, especially for carnivorous fish. In this study, experimental data and a literature meta-analysis were combined to understand microplastic translocation to fish tissue and egestion rates. Juvenile barramundi ( Lates calcifer ) were exposed through their diet to polyamide (PA) fibres and polyethylene terephthalate (PET) fibres and fragments (8–547 μm in length) to determine if shape, size, and polymer type influence microplastic translocation and egestion rates. Despite the high concentration (∼5000 microplastics g −1 ) and variable range of PET sizes and shapes used, their translocation from the GIT into other tissues was not observed, thus demonstrating PET fragments and fibres are unlikely to accumulate within barramundi. Moreover, more than 90% of all ingested PET microplastics were egested in less than 24 h, with only one small fragment persisting to 96 h post exposure. Elimination half-lives ranged from 9.2 to 12.2 h, with small PET fragments egested at a faster rate than the larger PET fragments and fibres but with no significant differences. Due to methodological challenges, PA fibres were unable to be quantified amongst the digesta. The meta-analysis of published fish egestion rates revealed that, when considering multiple fish, gut morphology (i.e., presence of a true stomach) rather than microplastic size and shape influenced egestion rates across species. The results presented here demonstrate no concrete evidence for GIT accumulation or translocation into tissue with rapid and efficient egestion of ingested microplastics by fish. These results suggest microplastics are not likely to bioaccumulate in barramundi and/or directly impact their associated food web. • Juvenile barramundi were exposed to PET fibres and fragments <547 μm through diet. • Small PET fragments (77 μm) were egested faster than large fragments (547 μm) and fibres (500 μm). • Fibres and fragments <547 μm were not present in the liver or muscle tissue up to 48 h after exposure. • More than 90% of all microplastics were egested within <24 h of exposure. • Meta-Analysis revealed microplastics egestion rates are dependent on gut morphology.

Topics & Concepts

MicroplasticsBarramundiJuvenileChromosomal translocationBiologyFisheryLatesZoologyEnvironmental chemistryFish <Actinopterygii>ChemistryEcologyBiochemistryGeneMicroplastics and Plastic PollutionRecycling and Waste Management TechniquesNanoparticles: synthesis and applications