Assessing the bioaccumulation of microplastics in commercially important fish species
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Abstract
Microplastics as defined in this study are plastic particles less than 5 mm in diameter. These particles have been highlighted in recent studies as a major concern due to their potency as pollutants. Microplastics endanger ecosystems and marine life, and, subsequently humans, and claim an ever-growing proportion of concern. This study examines bioaccumulation of microplastic contaminants found in commercial-grade fish stocks from coastal and offshore waters. The study incorporates species considered crucial to the fisheries and aquaculture industries on a global scale. It further assesses the extent, concentration, and characteristics of microplastics located within the gastrointestinal tracts and tissues of the target fish. Key maritime zones were sampled. Recovery of microplastics was achieved by density separation and enzymatic digestion, and polymes were identified using Fourier-transform Infrared spectroscopy (FTIR). Interspecies differences were significant in regard to microplastic accumulation and this study attributes this to differences in animals’ feeding strategies, depth of their habitats, and their trophic position. Both pelagic and demersal species showed differences in burdening microplastics with filter feeders and omnivorous species having more. These add up to the diet-based differences between trophic levels. Concern for the safety of seafood products and potential risks to human consumers highlight the danger of long- term consequences on fish tissue. These findings highlight the necessity to improve the regulation of marine litter, waste disposal in the vicinity of fishing harbors, and to implement comprehensive surveillance systems from a maritime viewpoint. Additionally, the results illustrate the need for plastic pollution stemming from anthropogenic activities to be managed for the sustainable economic and ecological protection of resources, constraining uncontrolled and detrimental spending on maintaining resources. This analysis provides fundamental information for the planning of marine preservation policies, advancing food safety for public health, and sustaining fragile coastal communities reliant on fisheries services.
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