Editorial: Impacts of emerging contaminants and their ecotoxicological consequences

Emerging Contaminants (ECs) in aquatic ecosystems have garnered global environmental concern with the advancement of detection and monitoring technologies. The increasing number and diversity of ECs have shown multiple impacts on biological systems, biodiversity, and ecosystem function in aquatic environments. Furthermore, adverse effects of ECs, particularly those that occur at environmentally relevant concentrations, may appear only when they co-occur with another stressor. However, knowledge about these impacts on aquatic species is still limited. Therefore, this research topic focused on exploring the linkages between exposure to emerging contaminants, the biological responses of aquatic species, and their potential ecological consequences, aiming to enhance our understanding of these critical environmental challenges. This Research Topic comprises 10 articles covering several aspects of emerging contaminants: the impacts and risk assessment of microplastics and nanoparticles, the toxic mechanisms of PPCPs, and the transfer and amplification of pollutants through the food chain.For the impacts of microplastics (MPs) and nanoparticles (NPs), Esterhuizen et al. (2024) investigated the ecotoxicological effects of polystyrene (PS) leachates on Daphnia magna and Artemia salina. Results showed higher mortality in A. salina exposed to seawater leachate, and sublethal concentrations triggered elevated antioxidant enzyme activities in both species. The findings underscored the need for monitoring species-specific impacts of MPs and their leachates. Inagaki et al. (2024) investigated the cytotoxic effects of titanium dioxide (TiO₂) NPs on the benthic foraminifer Ammonia veneta. The results indicated that TiO₂-NPs at ≥ 5ppm could disrupt the foraminiferal detoxification system.Studies also provide some new evidence that co-exposure to MPs and chemical contaminants may alter the combined toxicity to aquatic species. Aldraiwish et al. Studies also suggested that the transfer and amplification of pollutants through the food chain could significantly increase their ecological risks. Zhang et al. (2024) analyzed the contamination of 14 per-and polyfluoroalkyl substances (PFAS) in the Saunders's gull (Larus saundersi) and its food chain in Yellow Sea coastal wetlands.The results suggested that PFSA could be transferred maternally in L. saundersi, with bivalves and polychaetes as the primary contributors to PFAS contamination in food sources. In addition, Ni et al. (2024) reported the transfer of radionuclides and radiation dose assessment for marine organisms on the eastern coast of Yantai City. Binder et al. (2025) assessed the ecotoxicological impacts of munitions leakage from WWII shipwrecks in the Belgian North Sea using caged blue mussels (Mytilus edulis) and fish (Trisopterus luscus). Multi-biomarker analysis revealed oxidative stress in mussels and lysosomal membrane destabilization. The findings highlight subcellular toxicity in mussels and underscore the ecological risks of historical munitions in marine environments.Overall, articles in this Research Topic provide some new insights into the impacts of emerging contaminants and their ecotoxicological consequences. The findings are crucial for the environmental risk assessment of these pollutants. Although there is increasing recognition of the importance of a multi-stressor approach to aquatic ecosystems, there is still a lack of knowledge on this topic, especially regarding the ecological consequences of the combined effects of emerging contaminants and other environmental stresses. Such studies are still needed to achieve a more comprehensive understanding of the potential ecotoxicological consequences of long-term exposure to emerging contaminants on aquatic species worldwide.