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20 resultsShowing papers similar to Acute exposure to microplastics induces metabolic disturbances and gut dysbiosis in adult zebrafish (Danio rerio)
ClearChronic Exposure of Adult Zebrafish to Polyethylene and Polyester-based Microplastics: Metabolomic and Gut Microbiome Alterations Reflecting Dysbiosis and Resilience
Researchers exposed adult zebrafish to polyethylene and polyester microplastics at environmentally relevant concentrations and found significant disruptions to metabolic pathways and gut microbiome composition. Polyethylene primarily affected cell membrane compounds and inflammation-related metabolites, while polyester altered lipid metabolism and gut bacterial interactions. The study reveals that chronic microplastic exposure can cause subtle but meaningful shifts in fish metabolism and gut health, even at low concentrations.
Microplastics induce intestinal inflammation, oxidative stress, and disorders of metabolome and microbiome in zebrafish
Researchers exposed zebrafish to polystyrene microplastics for 21 days and found significant intestinal inflammation, oxidative stress, and disruption of both the gut microbiome and metabolic processes. The microplastics altered the balance of beneficial and harmful gut bacteria and changed the levels of key metabolites involved in energy and amino acid metabolism. The study provides detailed evidence that microplastic ingestion can cause widespread disruption to gut health in aquatic organisms.
Effects of polyethylene microplastics on the microbiome and metabolism in larval zebrafish
Researchers exposed zebrafish embryos to polyethylene microplastics for seven days and found significant disruptions to their gut bacteria and metabolic function. The microplastics altered the balance of key bacterial groups in the gut, increasing potentially harmful species while decreasing beneficial ones. Metabolic analysis revealed changes in fat, cholesterol, and sugar processing, suggesting that early-life microplastic exposure can disturb both the microbiome and metabolic development in fish.
Polystyrene microplastics induce gut microbiome and metabolome changes in Javanese medaka fish (Oryzias javanicus Bleeker, 1854)
Researchers found that polystyrene microplastic exposure altered gut microbiome composition and metabolic profiles in Javanese medaka fish, with effects on amino acid and lipid metabolism pathways suggesting microplastics can disrupt gut health in aquatic organisms.
Comparison of metabolome profiles in zebrafish (Danio rerio) intestine induced by polystyrene microplastics with different sizes
Researchers compared metabolic profiles in zebrafish intestines after exposure to polystyrene microplastics of different sizes, finding that smaller particles caused more severe metabolic disruption including altered lipid metabolism and amino acid pathways in a size-dependent manner.
Effects of polystyrene microplastics on the composition of the microbiome and metabolism in larval zebrafish
Researchers exposed larval zebrafish to two sizes of polystyrene microplastics and found significant changes in gut microbiome composition and metabolic activity. The microplastics altered the abundance and diversity of gut bacteria and disrupted metabolic pathways important for development. The study suggests that early-life exposure to microplastics could have meaningful biological consequences by reshaping the gut environment of developing organisms.
Metabolomic profiling reveals the intestinal toxicity of different length of microplastic fibers on zebrafish (Danio rerio)
Researchers exposed zebrafish to microplastic fibers of two different lengths and found that longer fibers caused more severe intestinal damage and reduced food intake by 54-67%. Metabolomic analysis revealed that the fibers disrupted lipid and fatty acid metabolism in the gut, promoting oxidative damage and inflammation. The study demonstrates that microplastic fiber length is an important factor in determining the severity of intestinal toxicity in aquatic organisms.
Polystyrene microplastic exposure disturbs hepatic glycolipid metabolism at the physiological, biochemical, and transcriptomic levels in adult zebrafish
Researchers exposed adult zebrafish to polystyrene microplastics for 21 days and examined effects on liver metabolism at multiple biological levels. The study found that microplastic exposure caused significant decreases in body weight and disrupted glycolipid metabolism, with reduced levels of key metabolic enzymes and gene expression changes in the liver. Transcriptomic analysis confirmed widespread downregulation of genes related to fatty acid, amino acid, and carbon metabolism.
Effects of MP Polyethylene Microparticles on Microbiome and Inflammatory Response of Larval Zebrafish
Zebrafish larvae exposed to polyethylene microplastics for up to 10 days showed no broad metabolic disturbances or inflammatory changes, but oxidative stress markers increased at 15 days and the gut microbiome was disrupted, with higher levels of bacteria linked to intestinal disease. The findings suggest microplastics alter the microbial environment of fish guts without triggering obvious inflammation.
Polystyrene microplastics induce microbiota dysbiosis and inflammation in the gut of adult zebrafish
Researchers exposed adult zebrafish to polystyrene microplastics of two different sizes for 14 days and found significant disruptions to the gut microbiome, including shifts in key bacterial populations. Smaller microplastic particles also triggered inflammatory responses in the gut, with elevated levels of inflammatory markers at both the gene and protein level. The study suggests that microplastic ingestion can disturb gut bacteria balance and cause intestinal inflammation in aquatic organisms.
Zebrafish exposure to high-density polyethylene and polystyrene microplastics: effects on liver transcriptome and gastrointestinal histology
This study used proteomics — the analysis of all proteins expressed by cells — to identify how zebrafish respond to exposure to high-density polyethylene and polystyrene microplastics, finding disruption of proteins involved in metabolism, oxidative stress, and immune defense. The protein-level analysis complements genomic approaches and reveals the biological mechanisms underlying microplastic toxicity in fish.
Effects on immunity of exposure to microplastics in adult zebrafish
Adult zebrafish exposed to microplastics showed changes in liver gene expression, gut and gill tissue damage, and altered swimming behavior, indicating that microplastic exposure triggers multiple biological stress responses. The study highlights the relevance of zebrafish as a model for assessing microplastic toxicity.
Acute toxic effects of polyethylene microplastic on adult zebrafish
Researchers exposed adult zebrafish to polyethylene microplastics of various sizes to identify physical effects, behavioral changes, and gene expression impacts. They found that microplastic ingestion varied by particle size and that exposure altered expression of detoxification and reproduction-related genes. The study suggests that microplastic pollution at environmentally relevant concentrations could affect both the health and reproductive capacity of fish.
Transcriptional effects of polyethylene microplastics ingestion in developing zebrafish (Danio rerio)
Researchers exposed developing zebrafish to polyethylene microplastics and used transcriptomic analysis to identify changes in gene expression related to immune function, lipid metabolism, and oxidative stress. The study suggests that even at relatively low concentrations, ingested microplastics can alter key biological pathways during early fish development.
Biomarker responses in zebrafish (Danio rerio) larvae exposed to pristine low-density polyethylene fragments
Researchers exposed zebrafish larvae to pristine low-density polyethylene microplastics and measured biomarker responses, finding altered oxidative stress and metabolic indicators even in early developmental stages.
Toxic effect of chronic exposure to polyethylene nano/microplastics on oxidative stress, neurotoxicity and gut microbiota of adult zebrafish (Danio rerio)
Researchers exposed adult zebrafish to polyethylene microplastics and nanoplastics for 21 days and found both caused oxidative damage to organs, disrupted brain function, and altered gut bacteria. Surprisingly, the toxic effects of microplastics and nanoplastics were similar in terms of brain and gut impacts, though organ-level oxidative damage varied by tissue type. These findings are concerning because they show that the plastic particles commonly found in food and water can simultaneously harm the brain, gut, and vital organs.
Toxicity of Polystyrene Nanoplastics in the Liver and Intestine of Normal and High-Fat-Diet Juvenile Zebrafish
Researchers exposed juvenile zebrafish to polystyrene nanoplastics combined with a high-fat diet and found that the combination caused gastrointestinal injury and disrupted lipid metabolism. The nanoplastics alone perturbed gut microbiota stability, and the effects were amplified when paired with a high-fat diet. The study suggests that dietary factors may influence the severity of nanoplastic toxicity, highlighting the importance of considering real-world exposure scenarios.
Polystyrene microplastics (PS-MPs): A Review on metabolic disruptions and potential obesogenic implications using -omics approaches based evidences on zebrafish model
This review summarizes growing evidence that polystyrene microplastics can disrupt fat and energy metabolism in zebrafish, potentially contributing to obesity-like effects. The microplastics altered lipid processing, energy balance, and gut bacteria composition through multiple biological pathways. These findings are relevant to human health because they suggest microplastics could be an overlooked factor in the global rise of obesity and metabolic disorders.
Particle size-dependent neurotoxicity of microplastics in zebrafish (Danio rerio): Spatially resolved lipidomics links metabolic dysregulation to neurological disorders
Researchers exposed zebrafish to polypropylene microplastics of different sizes and used spatial lipidomic imaging to show size-dependent disruptions in brain lipid metabolism, linking smaller particles to greater neurological disruption and identifying specific lipid dysregulation patterns.
Differential effects of foodborne and waterborne micro(nano)plastics exposure on fish liver metabolism and gut microbiota community.
Nile tilapia exposed to equivalent doses of micro(nano)plastics via food versus water showed distinct liver gene expression profiles, indicating that exposure route critically shapes the metabolic and toxicological response. Foodborne MNP exposure produced more pronounced effects on lipid metabolism and inflammation pathways.