Scientists find way to neutralize microplastic toxins in water using natural compounds
Researchers developed a hybrid material combining biosurfactants with microplastics that significantly reduced poisoning in aquatic organisms exposed to plastic pollution. The breakthrough offers a potential treatment method for contaminated waterways, with implications for water utilities, environmental remediation companies, and regulators facing mounting microplastic contamination.
Originaltitel: Intrinsic interaction inferred oxidative stress and apoptosis by Biosurfactant-microplastic hybrid reduces coordinated<em> in</em><em> vivo</em> biotoxicity in zebrafish (<em> Danio</em><em> rerio)</em>
<p>The proliferation of microplastics (μP) in aquatic environments poses a significant threat to ecosystem health, with repercussions extending to aquatic organisms and potentially to human health. In this study, we investigated the efficacy of a novel biosurfactant-microplastic (BSμP) hybrid in reducing <em>in vivo</em> green bio-toxicity of microplastics (μP) induced by oxidative stress and apoptosis in zebrafish (<em>Danio rerio</em>). Microplastics, ubiquitous in aquatic environments, were hybridised with Biosurfactant to evaluate their potential mitigating effects. A stable BSμP was formed with zeta potential of −10.3 ± 1.5 mV. Exposure of zebrafish embryos to μP resulted in increased oxidative stress markers, including elevated levels of reactive oxygen species and induced apoptosis, as evidenced by increased expression of apoptotic markers and morphological changes in embryonic zebrafish. However, the BSμP hybrid significantly ameliorated the observed toxic effects with reduced levels of oxidative stress markers and apoptotic activity. This effect was deduced as the intrinsic effects of hybridisation, which likely mitigated the bioavailability and toxicity of μP by reducing their molecular interaction with metabolic proteins like Sod1 and p53 through less accumulation and internalisation. Overall, our findings highlight the potential of BSμP as a promising approach for mitigating the ecological impacts of microplastic pollution.</p>