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20 resultsShowing papers similar to Impacts of polystyrene nanoplastics on zebrafish gut microbiota and mechanistic insights
ClearInteractions between intestinal microbiota and metabolites in zebrafish larvae exposed to polystyrene nanoplastics: Implications for intestinal health and glycolipid metabolism
Zebrafish larvae exposed to polystyrene nanoplastics suffered intestinal damage, including inflammation, oxidative stress, and disrupted gut bacteria -- with increases in bacteria linked to gut disease. The nanoplastics also altered metabolism related to sugar and fat processing, suggesting that ingesting these tiny particles could harm digestive health and disrupt how the body processes nutrients.
Effect of polystyrene nanoplastics on the intestinal histopathology, oxidative stress, and microbiota of Acrossocheilus yunnanensis
Researchers studied the effects of polystyrene nanoplastics on the intestinal health of a freshwater fish species and found significant damage to the gut lining, including ruptured tissue and damaged nutrient-absorbing structures. The nanoplastics also increased oxidative stress markers and shifted the composition of gut bacteria, reducing beneficial species. The findings suggest that nanoplastic exposure can compromise both the physical barrier and microbial balance of fish intestines.
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.
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.
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.
Polystyrene nanoplastics-induced intestinal barrier disruption via inflammation and apoptosis in zebrafish larvae (Danio Rerio)
Zebrafish larvae exposed to polystyrene nanoplastics showed significant gut damage, including increased cell death, inflammation, and breakdown of the intestinal barrier. The nanoplastics accumulated in the digestive tract and triggered chemical changes that suggest the plastic particles interact with biological tissue. Since zebrafish share many genetic similarities with humans, these findings raise concerns that nanoplastic ingestion could damage the human gut lining.
Polystyrene nano/microplastics induce microbiota dysbiosis, oxidative damage, and innate immune disruption in zebrafish
Researchers exposed zebrafish to polystyrene particles of two different sizes and found that both nano- and micro-sized plastics disrupted gut bacteria, caused oxidative damage, and altered immune responses. The severity of effects depended on particle size and concentration, with smaller particles and higher doses causing more harm. The study suggests that plastic particles in waterways may pose a broader threat to fish health than previously understood, affecting digestion, stress defenses, and immunity simultaneously.
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.
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.
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 nanoplastics disrupt the intestinal microenvironment by altering bacteria-host interactions through extracellular vesicle-delivered microRNAs
Researchers found that polystyrene nanoplastics disrupt the gut lining in mice by altering tiny RNA molecules that control the production of protective proteins in the intestinal barrier. The nanoplastics also caused an imbalance in gut bacteria, creating a chain reaction where damaged gut cells release particles that further weaken the intestinal barrier and change the microbiome.
Polystyrene microplastics induce endoplasmic reticulum stress, apoptosis and inflammation by disrupting the gut microbiota in carp intestines
Researchers fed carp polystyrene microplastics and found that the particles disrupted their gut bacteria, killing off beneficial species and promoting those linked to diseases. The microplastics triggered a stress response in intestinal cells that led to inflammation, cell death, and tissue damage. Since carp is a widely eaten fish, these gut health effects raise questions about how microplastics in aquatic environments could affect the safety of fish that humans consume.
The toxicity of polystyrene micro- and nano-plastics on rare minnow (Gobiocypris rarus) varies with the particle size and concentration
Scientists exposed rare minnow fish to polystyrene microplastics and nanoplastics at different sizes and concentrations and found that both caused growth inhibition, tissue damage, and disrupted gut bacteria. Interestingly, larger microplastics at high concentrations were the most disruptive to gut microbiome communities, while nanoplastics caused more oxidative stress. The study shows that the health effects of plastic particles depend on both their size and amount, and that gut health is a key target of microplastic toxicity.
Polystyrene Nanoplastics Toxicity to Zebrafish: Dysregulation of the Brain–Intestine–Microbiota Axis
This study found that polystyrene nanoplastics disrupted the brain-gut connection in zebrafish at environmentally realistic concentrations, affecting growth, gut health, and brain chemistry. The nanoplastics altered neurotransmitter levels, particularly reducing a dopamine-related compound, and changed the balance of gut bacteria in ways that correlated with brain changes. These findings suggest a pathway by which nanoplastics in food and water could affect both digestive and brain health through the gut-brain axis.
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.
Polystyrene nanoplastics sequester the toxicity mitigating potential of probiotics by altering gut microbiota in grass carp (Ctenopharyngodon idella)
Researchers tested whether probiotic pretreatment could protect grass carp from the toxic effects of polystyrene nanoplastics on gut health. While probiotics initially boosted immune responses and reduced intestinal damage, the protective effect was not strong enough to fully counteract nanoplastic toxicity over time. The study suggests that nanoplastics can undermine the gut health benefits of probiotics by disrupting the balance of gut bacteria.
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.
Effects of polystyrene nanoplastics on oxidative stress, histopathology and intestinal microbiota in largemouth bass (Micropterus salmoides)
Researchers exposed largemouth bass — a commercially important freshwater fish — to polystyrene nanoplastics (tiny plastic particles 100 nanometers in size) for up to 19 days, finding tissue damage in the gills, liver, and intestines along with elevated markers of cellular stress. While growth was not significantly affected, the fish adjusted their gut microbiome in response, suggesting nanoplastics trigger adaptive but potentially harmful physiological changes.
Adverse effects of polystyrene nanoplastics on sea cucumber Apostichopus japonicus and their association with gut microbiota dysbiosis
Researchers used multiple advanced techniques to study how polystyrene nanoplastics affect sea cucumbers, an important aquaculture species. They found that nanoplastic exposure disrupted the animals' gut microbiome, triggered inflammation, and impaired immune function. The study suggests that nanoplastic pollution in aquaculture environments could harm the health of commercially farmed marine species.
Understanding the links between micro/nanoplastics-induced gut microbes dysbiosis and potential diseases in fish: A review
This review examines how microplastics and nanoplastics accumulate in fish intestines and disrupt their gut bacteria, potentially leading to inflammation, immune problems, and metabolic diseases. The disrupted gut microbiome can weaken the intestinal barrier, allowing harmful substances to enter the fish's body. Since fish are a major protein source for billions of people, understanding how microplastics damage fish gut health is important for assessing risks to human food safety.