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61,005 resultsShowing papers similar to Gut Check: Microbiota and Obesity in Mice Exposed to Polystyrene Microspheres
ClearLong-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 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.
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.
Polystyrene microplastics trigger adiposity in mice by remodeling gut microbiota and boosting fatty acid synthesis
Researchers discovered that polystyrene microplastics at relatively low concentrations caused weight gain and excess fat accumulation in mice by reshaping their gut bacteria. The altered gut microbiome boosted fatty acid production, increased appetite, and lowered physical activity in the exposed mice. This finding is significant because it suggests everyday levels of microplastic exposure could contribute to obesity through changes in gut bacteria and metabolism.
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.
Polystyrene microplastic exposure induces insulin resistance in mice via dysbacteriosis and pro-inflammation
Researchers found that exposing mice to polystyrene microplastics induced insulin resistance regardless of whether the animals were on a normal or high-fat diet. The study identified disruption of gut bacteria and increased intestinal inflammation as key mechanisms driving the metabolic changes. These findings suggest that microplastic exposure may contribute to metabolic health issues by altering the gut microbiome and triggering chronic inflammation.
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.
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.
The impact of microplastics on the mice gut microbiome: a meta-analysis
This meta-analysis pools data from multiple mouse studies to assess how ingested microplastics affect gut bacteria. It found that microplastic exposure can alter the balance of the gut microbiome, which is important because gut health is closely tied to immune function, digestion, and overall well-being.
Deciphering Gut Microbiome Responses upon Microplastic Exposure via Integrating Metagenomics and Activity-Based Metabolomics
Using advanced metagenomics and metabolomics techniques, researchers studied how polystyrene microplastic exposure affects the gut microbiome in mice. The study found that microplastics disrupted the balance of gut bacteria and altered metabolic pathways related to amino acids and lipids. These findings suggest that microplastic exposure could influence gut health and metabolism, though more research is needed to understand the implications for human health.
Polystyrene microplastics exposure increases the disruption of intestinal barrier integrity and gut microbiota homeostasis during obesity and aging
Researchers found that polystyrene microplastic exposure worsened intestinal barrier dysfunction in mice on high-fat diets, with the combination of obesity and microplastic exposure producing greater gut permeability and inflammation than either factor alone, suggesting compounding risks in metabolically vulnerable individuals.
Gut microbiota and metabolic health risks from chronic low-dose microplastic exposure with focus on Desulfovibrio spp.
Researchers investigated the effects of long-term, low-dose polystyrene microplastic intake on gut bacteria and metabolism in mice. They found that even low doses significantly altered the gut microbiome, increasing bacteria linked to gastrointestinal inflammation and colorectal cancer risk, while also disrupting lipid and amino acid metabolism. The study suggests that routine microplastic exposure through food and water could quietly shift gut health in ways associated with chronic metabolic conditions.
Microbiome: A forgotten target of environmental micro(nano)plastics?
This review examines how micro- and nanoplastics affect the microbiome of various organisms, an area that has received less attention than other toxicological endpoints. Researchers found that most studies focused on polystyrene particles and that exposure consistently disrupted microbiome composition, triggered immune responses, and altered enzyme activity across organisms including crustaceans, fish, and mammals. The study highlights the microbiome as an important but often overlooked target of microplastic pollution.
The role of gut microbiota in mediating increased toxicity of nano-sized polystyrene compared to micro-sized polystyrene in mice
This mouse study found that nano-sized polystyrene plastics were significantly more toxic than micro-sized ones, causing greater gut inflammation, liver damage, and metabolic disruption. The key difference was driven by how each size affected gut bacteria: nanoplastics caused a more severe shift toward harmful bacteria and away from beneficial ones. The findings suggest that the smallest plastic particles may pose the greatest health risk because they more dramatically disrupt the gut microbiome.
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 reduces macrophages and affects the microbiota–gut–brain axis in mice
Mice that consumed polystyrene microplastics over an extended period showed reduced immune cells called macrophages in their colons and changes in gut bacteria that were linked to altered brain chemistry. This study provides evidence for a gut-brain connection where microplastics may affect brain function indirectly by first disrupting gut health and the immune system.
Impact of Microplastic Exposure on Blood Glucose Levels and Gut Microbiota: Differential Effects under Normal or High-Fat Diet Conditions
Mice exposed to polystyrene microplastics showed changes in blood sugar levels and gut bacteria, with the effects being worse when combined with a high-fat diet. The microplastics disrupted the balance of beneficial gut bacteria and increased markers associated with type 2 diabetes. This study suggests that microplastic exposure could contribute to blood sugar problems in people, especially those who already eat an unhealthy diet.
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.
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.
Integrated fecal microbiome and metabolome analysis explore the link between polystyrene nanoplastics exposure and male reproductive toxicity in mice
Researchers exposed mice to polystyrene nanoplastics of different sizes and doses, then analyzed fecal microbiome and metabolome changes alongside reproductive outcomes. The study found that nanoplastic exposure disrupted gut microbiota balance and metabolic pathways, which correlated with reduced sperm count, viability, and testosterone levels. The findings suggest that gut microbiota-metabolite disruption may play an important role in nanoplastic-induced male reproductive toxicity.
Polystyrene micro- and nanoplastics in a colitis mouse model – effects on biodistribution, macrophage polarization, and gut microbiome
Researchers exposed colitis mouse models to polystyrene micro- and nanoplastics to test whether MNP exposure worsens inflammatory bowel disease, finding that MNPs altered biodistribution and exacerbated inflammatory responses in animals with pre-existing gut inflammation.
Long-Term Exposure to Environmentally Relevant Doses of Large Polystyrene Microplastics Disturbs Lipid Homeostasis via Bowel Function Interference
Researchers exposed mice to environmentally relevant doses of large polystyrene microplastics in their diet for 21 weeks and found significant disruptions to fat metabolism and gut bacterial communities. The microplastics interfered with bowel function, which in turn altered how the body processes and stores lipids. The study provides evidence that even low-level, long-term microplastic exposure through food may affect metabolic health in mammals.
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.
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.