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61,005 resultsShowing papers similar to Dysbiosis of gut microbiota in C57BL/6-Lepem1hwl/Korl mice during microplastics-caused hepatic metabolism disruption
ClearPolystyrene microplastics induce gut microbiota dysbiosis and hepatic lipid metabolism disorder in mice
Researchers fed mice two sizes of polystyrene microplastics for five weeks and observed significant disruption of gut bacteria and changes in liver fat metabolism. The microplastics decreased mucus production in the gut and shifted the balance of key bacterial populations at multiple taxonomic levels. The study suggests that microplastic ingestion can trigger gut microbiota imbalance in mammals, which may in turn affect metabolic health.
Disruption of hepatic metabolism in Lep KO mice.
Researchers found that polystyrene microplastics administered orally for nine weeks accumulated in liver tissue of leptin-knockout obese mice and induced histopathological liver alterations, including disruption of hepatic lipid, glucose, and amino acid metabolism.
Supporting information.
Researchers found that nine weeks of oral polystyrene microplastic administration disrupted hepatic lipid, glucose, and amino acid metabolism in leptin-knockout obese mice while also altering fecal microbiota composition, suggesting that microplastic exposure compounds metabolic dysfunction in obesity.
Impact of the Oral Administration of Polystyrene Microplastics on Hepatic Lipid, Glucose, and Amino Acid Metabolism in C57BL/6Korl and C57BL/6-Lepem1hwl/Korl Mice
Researchers investigated the effects of orally administered polystyrene microplastics on liver metabolism in normal and obese mice over eight weeks. They found that microplastic exposure altered lipid, glucose, and amino acid metabolism pathways in the liver and adipose tissues. The study suggests that microplastic ingestion may disrupt hepatic metabolic functions, with potentially different impacts depending on baseline metabolic health status.
Chronic exposure to polyethylene terephthalate microplastics induces gut microbiota dysbiosis and disordered hepatic lipid metabolism in mice
Researchers found that mice exposed to PET microplastics (the type commonly found in plastic bottles) over 17 weeks developed liver damage, including fat buildup, oxidative stress, and cell death. The study revealed that the damage was driven by changes in gut bacteria that altered lipid metabolism, and when researchers depleted the gut bacteria, the liver damage was reduced. This suggests the gut microbiome plays a key role in how microplastics cause harm to internal organs.
Comparative Analysisof Metabolic Dysfunctions Associatedwith Pristine and Aged Polyethylene Microplastic Exposure via theLiver-Gut Axis in Mice
Researchers fed mice low doses of pristine and aged polyethylene microplastics for several weeks and analyzed changes in blood metabolites, liver proteins, and gut bacteria. Both forms caused lipid metabolism disruptions and reduced beneficial gut bacteria, with aged microplastics showing greater toxicity linked to changes in fatty acid processing enzymes.
Molecular Landscape Remodeling Unravels the Cross-Links of Microplastics-Induced Lipidomic Fluctuations, Nutrient Disorders and Energy Disarrangements
Researchers fed mice polypropylene microplastics chronically and used lipidomics and transcriptomics to show that microplastics accumulated in the liver and disrupted lipid metabolism, cholesterol homeostasis, and redox balance, with high doses causing fibrotic liver changes.
Molecular LandscapeRemodeling Unravels the Cross-Linksof Microplastics-Induced Lipidomic Fluctuations,Nutrient Disorders and Energy Disarrangements
Proteomic and lipidomic profiling of mouse livers after polypropylene microplastic exposure revealed crosstalk between hepatic lipid fluctuations, nutrient metabolism disorders, and energy pathway disarrangements, providing mechanistic insight into microplastic-induced liver toxicity.
Molecular LandscapeRemodeling Unravels the Cross-Linksof Microplastics-Induced Lipidomic Fluctuations,Nutrient Disorders and Energy Disarrangements
This study examined how polypropylene microplastics accumulate in and damage the mouse liver, using integrated lipidomics and transcriptomics to map the molecular landscape of microplastic-induced lipid disruption and metabolic dysfunction.
Effects of frying on microplastics load in fish and implications on health
Researchers investigated the effects of polyethylene microplastics on gut microbiota composition in mice fed a high-fat diet, finding that microplastic exposure altered microbial diversity and increased gut permeability. Co-exposure with a high-fat diet amplified metabolic disruption.
Molecular LandscapeRemodeling Unravels the Cross-Linksof Microplastics-Induced Lipidomic Fluctuations,Nutrient Disorders and Energy Disarrangements
Mouse liver studies with polypropylene microplastics revealed interconnected disruptions in lipid metabolism, nutrient processing, and energy balance, with proteomic and transcriptomic data highlighting the complexity of hepatic responses to chronic microplastic exposure.
Molecular LandscapeRemodeling Unravels the Cross-Linksof Microplastics-Induced Lipidomic Fluctuations,Nutrient Disorders and Energy Disarrangements
This study assessed the liver toxicity of polypropylene microplastics in mice using combined lipidomics and transcriptomics, identifying disrupted lipid metabolism, altered cholesterol handling, and fibrotic tissue remodeling as key pathological outcomes.
Molecular LandscapeRemodeling Unravels the Cross-Linksof Microplastics-Induced Lipidomic Fluctuations,Nutrient Disorders and Energy Disarrangements
Researchers used combined lipidomic and transcriptomic analysis to demonstrate that polypropylene microplastics accumulated in mouse liver and disrupted key metabolic pathways including lipid biosynthesis, cholesterol metabolism, and energy homeostasis.
Oral exposure to polyethylene microplastics of adult male mice fed a normal or western-style diet: impact on gut and gut-liver axis homeostasis
Researchers exposed adult male mice to polyethylene microplastics on normal or Western diet for 90 days, examining synergistic effects between plastic and dietary stress on gut and liver health. Microplastic exposure disrupted gut barrier integrity, altered the microbiome, and affected liver homeostasis, with some effects differing between normal and Western diet groups.
Oral exposure to high concentrations of polystyrene microplastics alters the intestinal environment and metabolic outcomes in mice
In a mouse study, oral exposure to high concentrations of polystyrene microplastics caused fatty liver disease and abnormal blood lipid levels even without prior gut leakiness. The microplastics triggered intestinal inflammation through immune cells, disrupted gut bacteria, and altered how the body processes nutrients. These results suggest that swallowing microplastics could contribute to metabolic problems and liver disease in humans.
Long-term exposure to polystyrene microplastics promotes HFD-induced obesity in mice through exacerbating microbiota dysbiosis
Researchers found that long-term polystyrene microplastic exposure worsened high-fat-diet-induced obesity in mice by exacerbating gut microbiota dysbiosis, suggesting microplastic ingestion may amplify metabolic disease risk through disruption of the gut microbiome.
Microbiota-mediated metabolic perturbations in the gut and brain of mice after microplastic exposure
In a mouse study, oral exposure to polystyrene microplastics of two sizes altered the gut bacteria community and caused metabolic changes in both the intestines and the brain. The disrupted gut bacteria appeared to drive changes in bile acid, energy, and other metabolic pathways. These findings support the idea that microplastics in food and water could affect brain health indirectly by first disrupting the gut microbiome and its chemical signals.
Oral exposure to polyethylene microplastics of adult male mice fed a normal or western-style diet: impact on gut and gut-liver axis homeostasis
Researchers orally exposed adult male mice to polyethylene microplastics under both normal and high-fat diets, assessing effects on the gastrointestinal tract. The study found that diet influences microplastic-induced gut changes, with greater effects observed in animals fed a western-style high-fat diet.
Lipidomics and transcriptomics insight into impacts of microplastics exposure on hepatic lipid metabolism in mice
Researchers used lipidomics and transcriptomics to examine how polystyrene microplastic exposure affects liver lipid metabolism in mice over eight weeks. The study found that while body weight and serum lipid levels were not significantly affected, microplastics caused impaired glucose metabolism and specific changes in hepatic lipid profiles, revealing subtle but measurable disruptions to liver function.
Polyethylene microplastics induced gut microbiota dysbiosis leading to liver injury via the TLR2/NF-κB/NLRP3 pathway in mice
Mice exposed to polyethylene microplastics developed liver damage that was traced back to disrupted gut bacteria -- the microplastics increased harmful bacteria while decreasing beneficial ones, triggering inflammation through the TLR2/NF-kB/NLRP3 immune pathway. This study provides new evidence that microplastics may harm the liver not just through direct contact, but indirectly by first throwing off the balance of gut bacteria.
Chronic PET‐Microplastic Exposure: Disruption of Gut–Liver Homeostasis and Risk of Hepatic Steatosis
Researchers exposed mice to PET microplastics ground from plastic bottles over 29 weeks and found that the particles caused obesity, liver enlargement, fatty liver disease, and early-stage scarring of liver tissue. The microplastics also disrupted gut bacteria and bile acid metabolism, pointing to damage along the gut-liver connection. The findings raise concerns about the long-term health effects of chronic exposure to the type of microplastics commonly found in food and beverages.
Proinflammatory properties and lipid disturbance of polystyrene microplastics in the livers of mice with acute colitis
Researchers studied the effects of polystyrene microplastics on the livers of mice fed a high-fat diet and found that the particles triggered significant inflammatory responses and disrupted lipid metabolism. The microplastics worsened fat accumulation in the liver and activated inflammatory signaling pathways. The findings suggest that microplastic exposure combined with a high-fat diet may amplify liver damage and metabolic disturbances.
Long-Term Exposure to Polystyrene Microspheres and High-Fat Diet-Induced Obesity in Mice: Evaluating a Role for Microbiota Dysbiosis.
A long-term mouse study examined how chronic exposure to polystyrene microspheres interacts with a high-fat diet to affect obesity-related outcomes, finding that microplastics worsened metabolic disruption and fat accumulation compared to diet alone. The results raise concern that microplastic exposure may be an environmental factor contributing to the global obesity epidemic.
Long-term exposure to polystyrene microplastics induces hepatotoxicity by altering lipid signatures in C57BL/6J mice
Researchers exposed mice to tiny polystyrene particles for 16 weeks and found the plastics accumulated in their livers, disrupting fat metabolism and energy production. The microplastics altered lipid profiles and interfered with key enzymes involved in cellular energy cycles. The study suggests that long-term microplastic exposure may contribute to liver damage through metabolic disruption.