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61,005 resultsShowing papers similar to The impact of microplastics on the mice gut microbiome: a meta-analysis
ClearIn vivo exposure of mixed microplastic particles in mice and its impacts on the murine gut microbiome and metabolome
Researchers exposed mice to a mixture of common microplastic types to investigate effects on the gut microbiome and metabolome. The study found that ingested microplastic particles altered gut microbial composition and disrupted metabolic pathways, suggesting that realistic mixed-microplastic exposure may have broader biological effects than single-polymer studies indicate.
Ecotoxicological impacts of microplastics to gut microbiota: Response mechanism, challenges and environmental sustainability-A review
This review summarizes how microplastics affect gut bacteria in fish, mice, and earthworms after being swallowed. Microplastics can change the balance of gut microbes and reduce their helpful functions, leading to digestive problems, slower growth, and weakened immunity. Since humans are exposed to microplastics through food and water, these findings raise concerns that our own gut health could be similarly affected.
Impacts of microplastics on gut health: Current status and future directions
This systematic review found consistent evidence across mouse, fish, and earthworm models that microplastics disrupt gut microbiota composition, impair intestinal barrier integrity, and trigger gastrointestinal inflammation. The correlation between microplastic exposure and gut health deterioration was statistically significant across all animal models examined.
Impacts of polystyrene microplastic on the gut barrier, microbiota and metabolism of mice
Researchers exposed mice to polystyrene microplastics for six weeks and found that the particles accumulated in the gut, reduced protective mucus secretion, and damaged the intestinal barrier. The microplastics also significantly altered the composition of gut bacteria, decreasing beneficial species and increasing harmful ones. The study suggests that microplastic ingestion could disrupt gut health in mammals by simultaneously impairing the physical barrier and reshaping the microbiome.
Gut Check: Microbiota and Obesity in Mice Exposed to Polystyrene Microspheres
Researchers found that gut microbiota appeared to play a mediating role in the obesity outcomes observed in mice fed manufactured polystyrene microspheres, suggesting that microplastic-induced alterations to the gut microbiome may be a mechanism linking microplastic exposure to metabolic dysfunction and weight gain.
Microplastic effects on mouse colon in normal and colitis conditions: A literature review
This literature review examined studies on how microplastic exposure affects the mouse colon under both normal and inflammatory conditions. Evidence indicates that microplastics may contribute to intestinal inflammation and could worsen existing colitis. The review highlights the need for further research to better understand how microplastic ingestion may influence gut health in humans.
Oral exposure to polyethylene microplastics alters gut morphology, immune response, and microbiota composition in mice
Researchers fed mice polyethylene microplastics of two sizes commonly found in human stool for six weeks and examined the effects on gut health. The study found that microplastic exposure altered gut structure, disrupted immune cell function, changed gene expression related to inflammation and gut barrier integrity, and shifted the composition of gut bacteria. Mice exposed to both sizes simultaneously showed the most severe effects, suggesting that real-world exposure to mixed microplastic sizes may compound the damage.
Polyethylene microplastics affect the distribution of gut microbiota and inflammation development in mice
Researchers fed mice different concentrations of polyethylene microplastics for five weeks and found significant changes in gut bacteria composition and signs of intestinal inflammation. Higher doses increased bacterial diversity and altered the balance of specific bacterial species, while triggering immune responses and inflammation in the colon and duodenum. The study provides evidence that microplastic ingestion can disrupt the gut microbiome and promote intestinal inflammation in mammals.
Unraveling Microplastic Effects on Gut Microbiota across Various Animals Using Machine Learning
This meta-analysis used machine learning to compare how microplastics affect gut bacteria across different animal species. Mice showed the strongest negative effects, including reduced gut bacterial diversity and imbalanced gut flora — shifts linked to health problems in humans too. The study identified specific bacterial markers, including Lactobacillus, that could help detect microplastic-related gut damage.
Review: interactions between microplastics and the gastrointestinal microbiome
This review summarizes existing research on how microplastics interact with the gut microbiome in humans, mice, chickens, and aquatic animals. Evidence suggests that gut bacteria can break microplastics into smaller pieces, which may make them more likely to cross the intestinal wall and enter the body. The disruption of the gut microbiome by microplastics is particularly concerning because balanced gut bacteria are essential for immune function, digestion, and overall health.
Perturbation of gut microbiota plays an important role in micro/nanoplastics-induced gut barrier dysfunction
Researchers investigated how micro- and nanoplastics disrupt gut barrier function in mice, finding that different surface chemistries caused varying levels of damage. The study suggests that these plastic particles harm the gut by altering the gut microbiome, which then leads to inflammation and weakening of the intestinal barrier that normally keeps harmful substances out of the body.
Interactions between polystyrene-derived micro- and nanoplastics and the microbiota: a systematic review of multi-omics mouse studies
Researchers systematically reviewed 15 mouse studies and found that exposure to polystyrene micro- and nanoplastics consistently disrupted gut bacteria — reducing beneficial species like Lactobacillus and increasing harmful ones — while also altering metabolic pathways throughout the body. Nanoplastics caused more severe microbiome disruption than larger microplastics, highlighting a serious health concern for humans.
How do microplastics affect the composition and function of gut microbiota?
Researchers reviewed how microplastics may disrupt gut microbiota composition and metabolic function, noting that while dysbiosis is a likely outcome of exposure, the full scope of these effects in humans remains understudied.
The ant that may well destroy a whole dam: a systematic review of the health implication of nanoplastics/microplastics through gut microbiota
This systematic review summarizes existing research on how nanoplastics and microplastics disrupt gut bacteria in various organisms. The findings show that plastic particle exposure consistently alters gut microbiome composition, which in turn affects the host's immune function, metabolism, and overall health. These gut bacteria changes may be a key pathway through which microplastics harm human health.
Polystyrene 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.
How do microplastics affect the composition and function of gut microbiota?
Researchers reviewed how microplastics may disrupt gut microbiota composition and metabolic function, noting that while dysbiosis is a likely outcome of exposure, the full extent of these effects in humans remains poorly characterized and understudied.
Gut microbiome remodeling induced by microplastic exposure in humans
This review synthesizes evidence on how microplastic exposure affects the human gut microbiome, drawing on cross-sectional studies of people exposed through plastic food containers and other sources. Evidence indicates that microplastic exposure is associated with shifts in gut bacteria composition, including increases in certain bacterial groups linked to inflammation. The authors explore potential connections between microplastic-induced changes in gut bacteria and the development of various health conditions.
Microbial risks associated with microplastics in the food chain and possible control measures (literature review). Part 1. Dietary intake and influence on the gut microbiota
This review summarizes evidence that microplastics commonly found in food and drinking water can disrupt the human gut microbiome when ingested. Studies show that microplastics alter the composition and function of intestinal bacteria, potentially affecting digestion, immunity, and overall health. Since a healthy gut microbiome is essential for human wellbeing, this pathway of harm deserves attention alongside other known risks of microplastic exposure.
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.
In vivo exposure of mixed microplastic particles in mice and its impacts on the murine gut microbiome and metabolome
Mice were orally exposed to a mixed polystyrene, polyethylene, and PLGA microplastic suspension for several weeks and gut microbiome composition and metabolomics were analyzed. Mixed microplastic exposure shifted the gut microbiome toward dysbiotic profiles in both male and female mice, with accompanying metabolome changes related to lipid and amino acid metabolism.
Micro(nano)plastics and Their Potential Impact on Human Gut Health: A Narrative Review
This review summarizes research on how micro- and nanoplastics affect the gut, finding that they can damage the intestinal lining, trigger immune responses, and disrupt the balance of beneficial gut bacteria in both cell studies and animal models. Since humans are primarily exposed to microplastics through food and food packaging, understanding these gut effects is essential for assessing the true health risks of plastic pollution.
Effects induced by polyethylene microplastics oral exposure on colon mucin release, inflammation, gut microflora composition and metabolism in mice
Researchers fed mice polyethylene microplastics for 30 days and found that even low doses reduced protective mucus in the colon, altered inflammation markers, and shifted the composition of gut bacteria. The microplastics increased the ratio of Bacteroides to Firmicutes bacteria and affected metabolic pathways in the gut microbiome. The study suggests that oral microplastic exposure may disrupt intestinal health by modifying the gut microbial community and its metabolism.
Impact of microplastics on the human gut microbiome: a systematic review of microbial composition, diversity, and metabolic disruptions
This systematic review of 12 studies found that microplastics including polyethylene, polystyrene, and PVC induce gut dysbiosis in humans, reducing beneficial bacteria and enriching pathogens. Microplastic exposure also impairs short-chain fatty acid production and modulates immune pathways, contributing to intestinal disease, metabolic syndrome, and chronic inflammation.
Continuous oral exposure to micro- and nanoplastics induced gut microbiota dysbiosis, intestinal barrier and immune dysfunction in adult mice
Researchers fed mice micro- and nanoplastics at environmentally relevant levels and found significant gut damage, including disrupted gut bacteria, weakened intestinal barriers, and reduced immune function. The ratio of beneficial to harmful gut bacteria shifted, and immune cells in the gut decreased. Importantly, the duration of exposure and the size of plastic particles mattered more than the amount consumed, suggesting even low-level long-term exposure could harm gut health.