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61,005 resultsShowing papers similar to The exploration of chronic combined toxic mechanisms of environmental PFOA and polyethylene micro/nanoplastics on adult zebrafish (Danio rerio), using aquatic microcosm systems
ClearCombined toxicity of polyethylene micro/nanoplastics and PFOA in zebrafish (Danio rerio): Impacts on antioxidant, neurotransmission, and gut microbiota
Researchers exposed zebrafish to polyethylene micro/nanoplastics and the industrial pollutant PFOA individually and in combination, assessing antioxidant capacity, neurotransmission, and gut microbiome composition. Combined exposure caused greater oxidative stress, more severe neurotransmitter disruption, and larger gut microbiome shifts than either contaminant alone, highlighting synergistic risks of co-occurring plastic and PFAS pollution.
Co-exposure to polystyrene microplastics and perfluorooctanoic acid can exacerbate lipid metabolism disorders and liver damage in adult zebrafish
Researchers exposed zebrafish to polystyrene microplastics and the persistent pollutant PFOA separately and together for 28 days, finding that combined exposure caused greater intestinal barrier breakdown, liver damage, lipid metabolism disruption, and gut microbiome dysbiosis than either contaminant alone — raising concerns about nonalcoholic fatty liver disease risk from co-occurring plastic and chemical pollution.
Combined exposure with microplastics increases the toxic effects of PFOS and its alternative F-53B in adult zebrafish
Researchers found that when zebrafish were exposed to microplastics along with PFOS or its replacement chemical F-53B (both are "forever chemicals"), the combined toxic effects were worse than either pollutant alone. The microplastics worsened liver inflammation, disrupted energy metabolism, and altered gut bacteria. This is relevant to human health because people are simultaneously exposed to both microplastics and PFAS chemicals through food and water.
Exacerbated interfacial impacts of nanoplastics and 6:2 chlorinated polyfluorinated ether sulfonate by natural organic matter in adult zebrafish: Evidence through histopathology, gut microbiota, and transcriptomic analysis
In a zebrafish study, nanoplastics combined with a fluorinated chemical pollutant and natural organic matter caused more severe liver and intestinal damage than any single pollutant alone. The mixture triggered greater oxidative stress, gut inflammation, and harmful changes to gut bacteria. This research shows that in the real world, where nanoplastics mix with other pollutants, the combined health effects may be worse than studies of individual chemicals suggest.
Polystyrene modulation of perfluorooctanoic acid toxicity in zebrafish: Transcriptomic and toxicological insights
Researchers exposed zebrafish to the industrial chemical PFOA both alone and in combination with polystyrene microplastics of different sizes to understand how the particles influence chemical toxicity. They found that PFOA disrupted neurotransmitter pathways, and the addition of microplastics modified this toxicity in a size-dependent manner, with smaller particles generally increasing harmful effects. The study provides evidence that microplastics can alter how other environmental pollutants affect living organisms.
Influence of microplastics on bisphenol A and bisphenol AF toxicity in aquatic environments: Mechanistic insights for environmental risks
Researchers investigated how polyethylene microplastics interact with the industrial chemicals bisphenol A and bisphenol AF in zebrafish, finding that microplastics can either reduce or worsen the toxicity depending on the specific chemical and biological pathway involved. For bisphenol A, the microplastics partially absorbed the chemical and reduced its harmful effects, but for bisphenol AF, they worsened toxicity to certain organ systems. The study reveals that microplastics play a complicated dual role in modifying how other pollutants affect aquatic life.
Toxicological effects of microplastics and phenanthrene to zebrafish (Danio rerio)
Researchers exposed zebrafish to polystyrene microplastics, the pollutant phenanthrene, and a combination of both to assess their toxicity over 24 days. They found that co-exposure amplified oxidative stress, suppressed immune gene expression, and significantly disrupted the gut microbiome compared to either contaminant alone. The study suggests that microplastics can worsen the toxic effects of organic pollutants in aquatic organisms by altering how chemicals accumulate and interact in the body.
Toxicity of microplastics and per- and polyfluoroalkyl substances in sentinel freshwater models, Daphnia, Zebrafish and unicellular green algae: A systemic review
Researchers reviewed 68 studies on how microplastics and PFAS ("forever chemicals") affect freshwater organisms like Daphnia, zebrafish, and algae, finding that both contaminants are more toxic at chronic low doses than in short-term exposures, and that combining them tends to amplify harm — while noting almost no research has studied them together.
Combined effects of microplastics and chemical contaminants on the organ toxicity of zebrafish ( Danio rerio )
Researchers studied the combined effects of microplastics and chemical contaminants like PCBs and methylmercury on zebrafish organs over three weeks of exposure. They found that microplastics carrying adsorbed contaminants produced the most significant effects, particularly on the liver, compared to either microplastics or contaminants alone. The results indicate that microplastics may act as carriers that increase the delivery of harmful chemicals to organisms' tissues.
Combined toxic effects of polyethylene microplastics and lambda-cyhalothrin on gut of zebrafish (Danio rerio)
Researchers found that polyethylene microplastics can adsorb the pesticide lambda-cyhalothrin from water and then release it in the guts of zebrafish, worsening its toxic effects. Fish exposed to both microplastics and the pesticide showed greater oxidative stress, immune disruption, and gut microbiome changes than those exposed to the pesticide alone. This demonstrates how microplastics can act as carriers that amplify the toxicity of other environmental pollutants in aquatic organisms consumed by humans.
Combined toxicity of perfluoroalkyl substances and microplastics on the sentinel species Daphnia magna: Implications for freshwater ecosystems
This study tested how PFAS chemicals (common industrial pollutants) and PET microplastics affect water fleas, both alone and together. The combination caused worse developmental and reproductive problems than either pollutant alone, and organisms with prior chemical exposure history responded differently, showing that microplastics can amplify the harm of other environmental contaminants in ways that are difficult to predict.
Single and combined toxicity effects of microplastics and perfluorooctanoic acid on submerged macrophytes and biofilms
Researchers tested the combined effects of four common microplastic types and PFOA (a forever chemical) on aquatic plants and their associated biofilms. The pollutants together caused more damage to plant growth, photosynthesis, and microbial communities than either pollutant alone. Since microplastics and PFOA frequently co-occur in the environment, their combined toxic effects on aquatic ecosystems could have downstream consequences for water quality and human exposure.
Developmental toxicity and mechanism of polychlorinated biphenyls 126 and nano-polystyrene combined exposure to zebrafish larvae
Researchers exposed zebrafish embryos to a combination of a toxic industrial chemical (PCB126) and nanoplastics and found that the mixture caused more severe developmental problems than either pollutant alone. The nanoplastics appeared to increase the absorption and toxic effects of PCB126, leading to greater heart defects and developmental abnormalities. The study suggests that nanoplastics may worsen the impact of existing chemical pollutants on aquatic life.
Toxic effects of polystyrene microplastics on atrazine in zebrafish: Exogenous toxicity and endogenous mechanism
Researchers found that combining polystyrene microplastics with the common herbicide atrazine was more toxic to zebrafish than either pollutant alone, causing greater liver and gut damage. The combination also degraded water quality by reducing oxygen levels and increasing harmful nitrogen compounds. This is important because microplastics and pesticides frequently co-exist in the environment, meaning their combined effects on aquatic life and food safety may be worse than studies of individual pollutants suggest.
Effects of single and combined exposure of virgin or aged polyethylene microplastics and penthiopyrad on zebrafish (Danio rerio)
This study found that polyethylene microplastics can increase the toxicity of a common fungicide (penthiopyrad) in zebrafish by helping the chemical build up in their bodies. The combination caused more intestinal damage and disrupted gut bacteria than either pollutant alone. This highlights an important concern: microplastics in the environment can act as carriers for pesticides, potentially amplifying their harmful effects on organisms including those in the human food chain.
Toxicity of parental co-exposure of microplastic and bisphenol compounds on adult zebrafish: Multi-omics investigations on offspring
When adult zebrafish were exposed to combinations of microplastics with bisphenol A (BPA) or bisphenol S (BPS), the reproductive damage was worse than from any single pollutant alone, and the effects carried over to their offspring. The BPA-microplastic combination primarily affected brain function, while BPS-microplastic exposure mainly disrupted visual development in the next generation. This study highlights that microplastics can amplify the harmful effects of common plastic chemicals, with consequences that extend to future generations.
Combined effects of polyethylene and organic contaminant on zebrafish (Danio rerio): Accumulation of 9-Nitroanthracene, biomarkers and intestinal microbiota
Researchers studied how polyethylene microplastics interact with the pollutant 9-Nitroanthracene in zebrafish, both individually and in combination. The study found that while microplastics can carry the pollutant into the fish, they actually reduced its accumulation by adsorbing it away from biological tissues. However, long-term combined exposure proved more toxic than either pollutant alone, suggesting delayed harmful effects when microplastics and chemical contaminants coexist in waterways.
Single and combined effects of polyethylene microplastics and acetochlor on accumulation and intestinal toxicity of zebrafish (Danio rerio)
This study found that polyethylene microplastics significantly increased the toxicity of acetochlor, a common herbicide, in zebrafish. The microplastics boosted the accumulation of the pesticide in fish tissues and worsened intestinal damage including inflammation and disrupted gut barrier function. The findings are important because microplastics and pesticides frequently co-exist in agricultural waterways, and their combination may pose greater risks than either pollutant alone.
Individual and Combined Toxic Effects of Nano-ZnO and Polyethylene Microplastics on Mosquito Fish (Gambusia holbrooki)
Researchers studied the individual and combined effects of polyethylene microplastics and zinc oxide nanoparticles on mosquito fish. The combination caused greater damage to liver tissue, blood parameters, and antioxidant systems than either pollutant alone. The findings suggest that microplastics interacting with other environmental contaminants can amplify toxic effects in aquatic organisms.
The Role of Synthetic Polymers in the Aquatic Environment and Its Implications in Danio Rerio as a Model Organism
Exposing zebrafish to polystyrene microplastics combined with silver nanoparticles caused significantly more oxidative damage, tissue injury in gills and intestines, and higher mortality than either contaminant alone. The study demonstrates that microplastics can act as carriers that enhance the toxicity of co-pollutants like silver nanoparticles, a combination effect that is highly relevant to understanding real-world aquatic contamination where multiple pollutants co-occur.
Interactive effects of polystyrene nanoplastics and 6:2 chlorinated polyfluorinated ether sulfonates on the histomorphology, oxidative stress and gut microbiota in Hainan Medaka (Oryzias curvinotus)
Researchers exposed a freshwater fish species to nanoplastics and a fluorinated chemical pollutant, both alone and in combination, and found that the mixture caused more severe tissue damage than either substance alone. The combined exposure harmed gills, liver, and intestines while disrupting antioxidant systems and gut bacteria. The study suggests nanoplastics can worsen the effects of industrial chemicals on aquatic life.
Additive effects of microplastics on accumulation and toxicity of cadmium in male zebrafish
Researchers exposed adult zebrafish to polyethylene microplastics and cadmium, both individually and in combination, for 21 days. They found that microplastics and cadmium together produced additive toxic effects, increasing cadmium accumulation in fish tissues, altering behavior, and causing more severe organ damage. The study suggests that microplastics in contaminated waterways may worsen the harmful effects of heavy metals on aquatic life.
Sorption of PFOS onto polystyrene microplastics potentiates synergistic toxic effects during zebrafish embryogenesis and neurodevelopment
Researchers found that polystyrene microplastics can absorb PFOS (a persistent industrial chemical) from water and deliver it to zebrafish embryos in a more concentrated form. The combination caused worse developmental problems than either pollutant alone, including delayed hatching, higher death rates, birth defects, and impaired brain development. This shows microplastics can act as carriers that intensify the toxic effects of other environmental chemicals.
Combined neurotoxicity of aged microplastics and thiamethoxam in the early developmental stages of zebrafish (Danio rerio)
This study found that aged (weathered) microplastics combined with the insecticide thiamethoxam caused worse neurological damage to zebrafish larvae than either pollutant alone. The combined exposure reduced heart rate and movement, disrupted antioxidant defenses, and altered neurotransmitter levels in ways that were synergistic rather than simply additive. This is relevant to human health because both microplastics and pesticides are common in the environment, and their combined effects may pose greater risks than either one individually.