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61,005 resultsShowing papers similar to Toxicological mechanisms and molecular impacts of tire particles and antibiotics on zebrafish
ClearHepatotoxicity, developmental toxicity, and neurotoxicity risks associated with co-exposure of zebrafish to fluoroquinolone antibiotics and tire microplastics: An in silico study
Using computer modeling, this study found that tire microplastics combined with common antibiotics caused significantly more liver damage in zebrafish than brain or developmental harm. The two pollutants worked together to amplify toxicity, meaning the combination was worse than either one alone. This highlights how microplastics in waterways can interact with other contaminants to create greater health risks for aquatic life and potentially for humans who consume seafood.
Co-exposure of TMPs and antibiotics in zebrafish: The influence of additives on the risk of hepatotoxicity
Researchers investigated how tire microplastics combined with antibiotics cause liver damage in zebrafish, focusing specifically on the role of chemical additives in the tire particles. They found that different antibiotic-tire microplastic combinations produced varying levels of liver toxicity, with certain additive chemicals playing a key role. The study suggests that the additives leaching from tire microplastics may be an underappreciated contributor to their environmental toxicity.
Co-exposure to microplastics and tire particles exacerbates oxidative stress and gut microbiome dysbiosis in zebrafish (Danio rerio)
Researchers exposed zebrafish for 21 days to environmentally relevant mixtures of microplastics and tire particles and found that combined exposure caused more severe oxidative stress and gut microbiome disruption than either pollutant alone. Particle accumulation occurred mainly in the gut with secondary deposition in the liver, and the most pronounced tissue damage was observed under the highest combined exposure. Gut microbiota analysis revealed significant shifts in community structure, including reduced beneficial bacteria and increased pollutant-tolerant species.
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.
Enhanced hepatotoxicity in zebrafish due to co-exposure of microplastics and sulfamethoxazole: Insights into ROS-mediated MAPK signaling pathway regulation
Zebrafish exposed to both microplastics and the antibiotic sulfamethoxazole (commonly found in waterways) suffered significantly worse liver damage than exposure to either pollutant alone. The combined exposure triggered a cascade of oxidative stress, inflammation, and cell death in liver tissue, showing how microplastics can amplify the harmful effects of other environmental contaminants.
Combined effect of microplastics and tire particles on Daphnia magna: Insights from physiological and transcriptomic responses
Researchers investigated the combined effects of microplastics and tire particles on the water flea Daphnia magna, finding that the mixture triggered significant oxidative stress at environmentally relevant concentrations. Transcriptomic analysis revealed upregulation of antioxidant and metabolic stress genes, while energy reserves like glycogen were affected. The study suggests that co-exposure to these common freshwater pollutants may pose greater ecological risks than either particle type alone.
Combined hepatotoxicity of imidacloprid and microplastics in adult zebrafish: Endpoints at gene transcription
Researchers investigated the combined liver toxicity of the pesticide imidacloprid and polystyrene microplastics in adult zebrafish over 21 days. The combination caused greater changes in gene expression related to fat and sugar metabolism and inflammatory responses than either contaminant alone. The study suggests that even low concentrations of microplastics and pesticides together may produce more severe hepatotoxic effects than individual exposures.
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.
Mixture toxicity of 6PPD-quinone and polystyrene nanoplastics in zebrafish
Researchers studied the combined toxicity of 6PPD-quinone, a toxic chemical from tire rubber, and polystyrene nanoplastics on zebrafish. While nanoplastics alone did not affect fish movement, the tire chemical caused hyperactivity, and the combination made this behavioral effect even worse. The study found that these co-occurring pollutants disrupted genes involved in brain signaling and fat metabolism, suggesting that real-world mixtures of plastic pollutants may be more harmful than individual ones.
Metabolic profile changes of zebrafish larvae in the single- and co-exposures of microplastics and phenanthrene
Researchers exposed zebrafish larvae to microplastics and the pollutant phenanthrene, both individually and together, and analyzed changes in their metabolic profiles. They found that combined exposure triggered unique metabolic disruptions not seen with either contaminant alone, particularly in amino acid metabolism pathways. The study provides evidence that microplastics and organic pollutants can interact to produce novel toxic effects in aquatic organisms.
Size-dependent ecotoxicological impacts of tire wear particles on zebrafish physiology and gut microbiota: Implications for aquatic ecosystem health
Researchers found that tire wear particles, a major but often overlooked source of microplastic pollution, affect zebrafish health differently depending on particle size. Smaller particles caused more severe gut microbiome disruption, oxidative stress, and immune responses, suggesting that tire-derived microplastics in waterways may pose a greater health risk to aquatic life than previously recognized.
Microplastics Enhance the Toxic Effects of Tetracycline on the Early Development of Zebrafish in a Dose-Dependent Manner
Researchers exposed zebrafish embryos and larvae to polyethylene microplastics combined with the antibiotic tetracycline and found that the combination enhanced toxic effects in a dose-dependent manner. The co-exposure caused increased mortality, reduced body length, cardiac abnormalities, and aberrant vascular development through mechanisms involving oxidative stress and inflammation. The findings demonstrate that microplastics can amplify the toxicity of antibiotics during critical early developmental stages in fish.
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.
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.
Microplastic-contaminated antibiotics as an emerging threat to mammalian liver: enhanced oxidative and inflammatory damages
Researchers used a mouse model to study what happens when microplastics contaminated with antibiotics are ingested together, simulating real-world food chain exposure. The study found that the combination caused enhanced oxidative stress and inflammatory damage in the liver compared to either pollutant alone. The findings suggest that microplastics carrying adsorbed antibiotics may pose a greater threat to liver health than microplastics or antibiotics individually.
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.
Polystyrene microplastics alter the toxicity of 6PPD to zebrafish (Danio rerio) larvae
Researchers investigated the combined toxicity of polystyrene microplastics and the tire-derived chemical 6PPD on zebrafish larvae. Co-exposure produced synergistic toxic effects, significantly increasing oxidative stress markers and altering metabolic profiles beyond what either pollutant caused individually. The study found that microplastics increased the concentration of the toxic transformation product 6PPD-quinone in zebrafish, suggesting they can enhance the chemical hazard of tire-related pollutants in aquatic environments.
The exploration of chronic combined toxic mechanisms of environmental PFOA and polyethylene micro/nanoplastics on adult zebrafish (Danio rerio), using aquatic microcosm systems
Researchers studied the combined toxic effects of polyethylene micro/nanoplastics and the chemical pollutant PFOA on zebrafish in conditions mimicking real aquaculture systems. They found that the combination produced time-dependent toxicity patterns, with effects on the liver, gut, and reproductive systems that were sometimes more severe than either pollutant alone. The study highlights that microplastics and industrial chemicals can interact in ways that amplify their individual harms to aquatic life.
Toxic 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.
Toxicity evaluation of the combination of emerging pollutants with polyethylene microplastics in zebrafish: Perspective study of genotoxicity, mutagenicity, and redox unbalance
Researchers exposed adult zebrafish to polyethylene microplastics combined with a mixture of common water pollutants for 15 days and assessed DNA damage, mutation rates, and oxidative stress. They found that microplastics alone caused DNA damage and nuclear abnormalities as severe as those caused by the pollutant mixture, challenging the assumption that microplastics are less harmful than chemical contaminants. The study revealed that the fish's antioxidant defenses were overwhelmed across multiple organs, suggesting widespread oxidative damage from microplastic exposure.
Polyethylene microplastic exposure and concurrent effect with Aeromonas hydrophila infection on zebrafish
Researchers found that polyethylene microplastic exposure in zebrafish caused oxidative stress, altered antioxidant enzyme activity, and induced intestinal damage, with concurrent Aeromonas hydrophila infection amplifying these toxic effects and increasing mortality rates.
The Exploration of Joint Toxicity and Associated Mechanisms of Primary Microplastics and Methamphetamine in Zebrafish Larvae
Researchers studied how microplastics and methamphetamine together affect zebrafish larvae, since both pollutants frequently co-occur in waterways. The study found that polystyrene microplastics were more lethal than PVC types, and when combined with methamphetamine at higher concentrations, the toxic effects on survival, behavior, and intestinal health became significantly worse.
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.
Cocktail effects of tire wear particles leachates on diverse biological models: A multilevel analysis
Tire wear particles, a major but underappreciated source of microplastic pollution, leached chemicals into seawater that inhibited algae growth, caused developmental problems in zebrafish embryos, and showed hormone-disrupting effects in cell tests. The study found that water-soluble organic compounds from tires -- not just heavy metals like zinc -- were the primary drivers of toxicity, underscoring the need for better regulation of tire additives.