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61,005 resultsShowing papers similar to Combined exposure to polystyrene nanoplastics and bisphenol A induces hepato- and intestinal-toxicity and disturbs gut microbiota in channel catfish (Ictalurus punctatus)
ClearToxic impacts of polystyrene nanoplastics and PCB77 in blunt snout bream: Evidence from tissue morphology, oxidative stress and intestinal microbiome
Researchers studied the combined toxicity of polystyrene nanoplastics and a persistent organic pollutant (PCB77) in freshwater fish. They found that co-exposure caused worse tissue damage, higher oxidative stress, and greater disruption to gut bacteria than either contaminant alone. The study highlights that microplastics can worsen the harmful effects of other environmental pollutants when organisms are exposed to both simultaneously.
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.
Co-exposure to polystyrene nanoplastics and mercury synergistically exacerbates toxicity in rare minnow (Gobiocypris rarus) compared to individual exposures
This study found that when nanoplastics and mercury are present together in water, their combined toxic effects on fish are significantly worse than either pollutant alone. Researchers observed that nanoplastics increased mercury accumulation in rare minnow tissue by about 33%, and the combination caused greater gut damage, inflammation, and disruption of beneficial gut bacteria. The findings highlight the importance of considering how multiple pollutants interact, rather than studying them in isolation.
Toxic effects of nanoplastics and microcystin-LR coexposure on the liver-gut axis of Hypophthalmichthys molitrix
Scientists exposed silver carp to both polystyrene nanoplastics and microcystin-LR (a toxin from harmful algae) and found the combination caused more severe gut and liver damage than either pollutant alone. The nanoplastics shortened intestinal structures, changed gut bacteria communities, and disrupted liver metabolism. This is concerning because both contaminants are commonly found together in aquaculture waters, and the fish affected are widely consumed by people.
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.
Effects of chronic co-exposure polystyrene nanoplastics and cadmium on liver function in Prussian carp (Carassius gibelio)
Researchers exposed Prussian carp to polystyrene nanoplastics and cadmium, both individually and together, for 21 days and found that the combination caused significantly worse liver damage than either pollutant alone. The nanoplastics enhanced cadmium accumulation in the liver and amplified oxidative stress, tissue damage, and immune gene activation. The findings demonstrate that nanoplastics and heavy metals can have synergistic toxic effects on aquatic organisms.
The combined exposure of polystyrene microplastics and high‐fat feeding affects the intestinal pathology damage and microbiome in zebrafish
Researchers exposed zebrafish to polystyrene microplastics combined with a high-fat diet and found that the combination caused more severe intestinal damage and greater disruption of gut bacteria than either exposure alone. The microplastics worsened inflammation and structural damage to the intestinal lining, particularly when paired with the high-fat feed. The study suggests that dietary factors may amplify the harmful gut effects of microplastic ingestion in aquatic organisms.
Integration of physiology, microbiota and metabolomics reveals toxic response of zebrafish gut to co-exposure to polystyrene nanoplastics and arsenic
Researchers exposed zebrafish to arsenic combined with polystyrene nanoplastics and found that the nanoplastics significantly increased arsenic accumulation in the gut, by up to 77% at the higher dose. The combined exposure caused more oxidative damage and greater disruption to gut bacteria and metabolism than arsenic alone. This study shows that nanoplastics can make other environmental pollutants more dangerous by helping them accumulate in the digestive system.
Nanoplastics enhance the intestinal damage and genotoxicity of sulfamethoxazole to medaka juveniles (Oryzias melastigma) in coastal environment
Scientists exposed young medaka fish to the antibiotic sulfamethoxazole and polystyrene nanoplastics, both individually and together, to study their combined effects on intestinal health. They found that co-exposure caused more severe gut damage than either pollutant alone, disrupting the gut microbiome and triggering changes in gene expression related to immune defense and DNA repair. The study suggests that nanoplastics may amplify the harmful effects of antibiotics on fish in coastal environments.
Synergistic Toxicity of Combined Exposure to Acrylamide and Polystyrene Nanoplastics on the Gut–Liver Axis in Mice
Researchers exposed mice to a combination of acrylamide, a common food processing byproduct, and polystyrene nanoplastics through drinking water and found that the combined exposure caused more severe gut and liver damage than either substance alone. The co-exposure disrupted gut barrier integrity, altered gut bacteria composition, and caused widespread metabolic changes. The study suggests that the interaction between nanoplastics and other food contaminants may amplify health risks beyond what each poses individually.
Polystyrene nanoplastic and engine oil synergistically intensify toxicity in Nile tilapia, Oreochromis niloticus
This study found that polystyrene nanoplastics and engine oil together caused much worse damage to Nile tilapia fish than either pollutant alone, triggering severe inflammation, blood cell changes, and oxidative stress. The combined exposure overwhelmed the fish's natural defenses and caused significant organ damage. Since tilapia is a widely consumed fish, this research highlights how mixtures of pollutants in waterways could compound health risks for both aquatic life and humans who eat contaminated seafood.
Combined impacts of microplastics and cadmium on the liver function, immune response, and intestinal microbiota of crucian carp (Carassius carassius)
Researchers exposed crucian carp to microplastics and cadmium, both alone and together, and found the combination caused more severe liver damage and immune disruption than either pollutant alone. Co-exposure also significantly altered the fish's gut bacteria after 21 days. This is concerning because microplastics and heavy metals frequently co-occur in polluted waterways, potentially amplifying harm to aquatic life.
Gut microbiota related response of Oryzias melastigma to combined exposure of polystyrene microplastics and tetracycline
Researchers exposed estuarine fish to polystyrene microplastics and the antibiotic tetracycline, both alone and in combination, for four weeks. The combined exposure caused more severe disruption to gut bacteria and liver tissue than either pollutant alone, with microplastics appearing to worsen the effects of tetracycline. The study suggests that the co-occurrence of microplastics and antibiotics in coastal waters may pose greater ecological risks than either contaminant by itself.
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.
Polystyrene nanoplastics synergistically exacerbate diclofenac toxicity in embryonic development and the health of adult zebrafish
When zebrafish embryos and adults were exposed to polystyrene nanoplastics combined with the common pain medication diclofenac, the mixture was significantly more harmful than either substance alone. The combination reduced hatching rates, increased mortality, caused developmental abnormalities, and triggered intestinal inflammation in adult fish. This finding is concerning because nanoplastics and pharmaceutical residues frequently coexist in waterways, and their combined effects on aquatic life could be worse than what studies of individual pollutants suggest.
Co-exposure to polystyrene microplastics and cypermethrin enhanced the effects on hepatic phospholipid metabolism and gut microbes in adult zebrafish
When zebrafish were exposed to both polystyrene microplastics and the pesticide cypermethrin together, the combination caused significantly more liver damage than either pollutant alone. The mixture disrupted fat metabolism in the liver and altered gut bacteria in ways not seen with individual exposures. This matters because microplastics and pesticides frequently co-exist in waterways, and their combined effects on fish health could affect the safety of fish as food.
Integrated analysis of zebrafish gut microbiota and liver transcriptome responses to polystyrene microplastics and cadmium
Researchers exposed zebrafish to polystyrene microplastics and cadmium, both individually and combined, and found that combined exposure caused more severe disruption to gut bacteria and liver gene expression than either pollutant alone. The study revealed that microplastics decreased beneficial gut bacteria while increasing pathogenic species, and the combined treatment suppressed liver xenobiotic metabolism and antioxidant pathways.
Combined impacts of organophosphate pesticide and polyamide microplastics on growth, hematology, and immune responses in juvenile striped catfish (Pangasianodon hypophthalmus)
Researchers exposed juvenile striped catfish to both polyamide microplastics and an organophosphate pesticide, finding that the combination caused more severe growth reduction, immune suppression, and organ damage than either pollutant alone — evidence that microplastics and pesticides can act together to amplify harm in freshwater fish.
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.
Combined effects of micro-/nano-plastics and oxytetracycline on the intestinal histopathology and microbiome in zebrafish (Danio rerio)
Researchers studied the combined effects of micro- and nano-sized plastics with the antibiotic oxytetracycline on zebrafish intestines over 30 days. Nano-sized plastics caused more intestinal damage than micro-sized ones, and combined exposures altered gut bacterial communities and increased antibiotic resistance genes. The findings suggest that the co-occurrence of plastic particles and antibiotics in aquatic environments may have compounding negative effects on fish gut health.
Enhanced neurotoxic effect of PCB-153 when co-exposed with polystyrene nanoplastics in zebrafish larvae
Researchers found that when zebrafish larvae were exposed to both polystyrene nanoplastics and the toxic chemical PCB-153 together, the neurological damage was significantly worse than from either pollutant alone. The combined exposure caused hyperactive swimming behavior and suppressed immune, brain, and detoxification pathways at the genetic level. This is concerning because nanoplastics and persistent organic pollutants frequently co-exist in the environment, meaning their real-world health effects on aquatic life and humans may be greater than studies of single pollutants suggest.
The combined effects of microplastics and bisphenol-A on the innate immune system response and intestinal microflora of the swimming crab Portunus trituberculatus
Swimming crabs exposed to both microplastics and bisphenol-A (BPA, a chemical found in many plastics) for 21 days showed weakened immune responses and disrupted gut bacteria compared to exposure to either pollutant alone. The combination caused more intestinal damage and greater shifts in gene activity related to immune defense. This suggests that microplastics and the chemicals they carry can work together to cause greater harm to marine organisms than either one would cause by itself.
Toxicity of co-exposure of microplastics and lead in African catfish (Clarias gariepinus)
Researchers exposed African catfish to lead, microplastics, and a combination of both for 15 days and found that the combined exposure was more harmful than either pollutant alone. The mixture caused the greatest damage to blood cells, triggered stronger inflammatory responses, and disrupted the fish's antioxidant defenses. Since microplastics can carry heavy metals like lead on their surfaces, this study shows how microplastics may amplify the toxic effects of other pollutants in freshwater fish that people eat.
Concurrent impacts of polystyrene nanoplastic exposure and Aeromonas hydrophila infection on oxidative stress, immune response and intestinal microbiota of grass carp (Ctenopharyngodon idella)
Researchers studied the combined effects of polystyrene nanoplastics and a bacterial infection on grass carp, a common freshwater fish. They found that nanoplastic exposure worsened the impact of the infection by increasing oxidative stress, suppressing immune responses, and disrupting the gut microbiome. The study suggests that nanoplastic pollution in waterways could make fish more vulnerable to disease by weakening their natural defenses.