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61,005 resultsShowing papers similar to Gut-lung axis: a novel mechanism involving microbiota dysbiosis-coordinated PLA2-TRPV1 neuroimmune crosstalk in nanoplastic-induced asthma exacerbation
ClearAirborne polystyrene microplastics and nanoplastics induce nasal and lung microbial dysbiosis in mice
Researchers found that airborne polystyrene microplastics and nanoplastics can induce microbial dysbiosis in the nasal passages and lungs of mice. The study showed that both micro- and nanoplastics altered airway microbiota composition, with microplastics having a stronger influence on lung bacterial communities, suggesting that inhaled plastic particles may disrupt respiratory microbial balance.
Gut-lung microbiota dynamics in mice exposed to Nanoplastics
Researchers gave mice PET nanoplastics orally for 28 days and analyzed the microbiome in their lungs, colon, mouth, and stool. While gut and oral bacteria were relatively unchanged, the lung microbiome showed significant shifts, including increases in bacteria associated with respiratory inflammation. The findings suggest a gut-lung connection where ingested nanoplastics may influence lung microbial communities even when gut bacteria appear unaffected.
Mechanisms underlying Th2-dominant pneumonia caused by plastic pollution derivatives (PPD): A molecular toxicology investigation that encompasses gut microbiomics and lung metabolomics
In a mouse study, exposure to dibutyl phthalate (a plastic additive) and polystyrene microplastics for five weeks caused pneumonia-like lung damage, increased oxidative stress, and triggered inflammation. The researchers found that these plastic pollution byproducts caused a specific type of immune response that leads to eosinophilic inflammation in the airways, connected through the gut-lung axis. The findings suggest that everyday exposure to plastic-derived chemicals and particles could contribute to respiratory disease.
Pulmonary Flora‐Derived Lipopolysaccharide Mediates Lung‐Brain Axis through Activating Microglia Involved in Polystyrene Microplastic‐Induced Cognitive Dysfunction
In a mouse study, inhaling polystyrene microplastics impaired learning and memory -- even though the plastics never reached the brain directly. Instead, the microplastics changed the bacterial community in the lungs, which produced inflammatory signals that traveled to the brain and triggered damage, revealing a lung-to-brain pathway for microplastic harm.
Lung microbiota participated in fibrous microplastics (MPs) aggravating OVA-induced asthma disease in mice
In a mouse study, inhaling fiber-shaped microplastics significantly worsened asthma symptoms, including airway inflammation, mucus buildup, and lung tissue scarring. The microplastic fibers also disrupted the balance of bacteria living in the lungs and activated inflammatory pathways. Since fibrous microplastics are the most common airborne shape and have been found in human lungs, this research suggests they could worsen respiratory conditions like asthma in people.
Nanoplastics Chronic Toxicity in Mice: Disturbing the Homeostasis of Tryptophan Metabolism in Gut‐Lung‐Microbiota Axis
Researchers studied how long-term nanoplastic exposure affects mice and found it caused inflammation in the colon and scarring in lung tissue by disrupting a key amino acid metabolism pathway connecting the gut and lungs. They discovered that a beneficial gut bacterium called Akkermansia muciniphila was depleted after exposure, and restoring it helped reduce the damage. The study suggests that supporting healthy gut bacteria may be a strategy for mitigating the harmful effects of nanoplastic exposure.
Presence of nanoplastics in sputum of patients with severe asthma: a novel environmental perspective
Researchers analyzed sputum from severe asthma patients and detected nanoplastics in samples for the first time, comparing concentrations and immune profiles across asthma phenotypes. Nanoplastic presence in sputum was associated with more severe disease and distinct immune dysregulation patterns, identifying environmental nanoplastic exposure as a potential modifier of asthma severity.
Oral exposure to nanoplastics and food allergy in mice fed a normal or high-fat diet
Researchers studied how oral exposure to polystyrene nanoplastics affects food allergy responses in mice fed either a normal or high-fat diet. They found that nanoplastics worsened allergic reactions to a food protein, particularly in mice on the high-fat diet, by increasing gut permeability and shifting immune responses. The study suggests that the combination of nanoplastic exposure and a Western-style diet may be contributing to the rising prevalence of food allergies.
Cellular and molecular mechanisms of allergic asthma
Researchers reviewed the cellular and molecular mechanisms behind allergic asthma, finding that rising exposure to environmental pollutants — including microplastics — likely contributes to the disease's increasing prevalence, as pollutants disrupt airway barrier integrity and trigger immune responses that lead to chronic airway inflammation.
Nanoplastic Impact on the Gut-Brain Axis: Current Knowledge and Future Directions
Researchers reviewed the emerging evidence on how nanoplastics may affect the gut-brain axis, the communication pathway between the digestive and nervous systems. Studies indicate that nanoplastic exposure can alter gut microbiota, increase intestinal permeability, trigger oxidative stress and inflammation, and produce neurotoxic and behavioral effects. The review calls for more research given the ubiquitous presence of plastics in the human environment and the potential for nanoplastics to disrupt this critical biological communication pathway.
Polystyrene nanoplastics induce intestinal and hepatic inflammation through activation of NF-κB/NLRP3 pathways and related gut-liver axis in mice
In a mouse study, ingested polystyrene nanoplastics accumulated in the gut and liver and triggered inflammation through specific immune pathways, damaging the intestinal lining and allowing bacterial toxins to leak into the liver. This gut-liver connection suggests that swallowing nanoplastics could set off a chain reaction of inflammation affecting multiple organs in the body.
Impact of Microplastic Exposure on Airway Inflammation in an Acute Asthma Murine Model
Mouse experiments found that microplastic exposure worsened inflammatory responses in healthy lungs but did not further aggravate airway inflammation in mice with pre-existing asthma, suggesting the lung's response to microplastics depends on baseline immune state.
Detrimental effects of microplastic exposure on normal and asthmatic pulmonary physiology
Researchers exposed both healthy and asthmatic mice to airborne microplastics and found significant lung inflammation, immune activation, and increased mucus production in both groups. Microplastic particles were taken up by immune cells called macrophages, and gene analysis revealed changes in immune response, cellular stress, and cell death pathways. The study suggests that inhaling microplastics may worsen respiratory health in both normal and vulnerable populations.
Polystyrene particles induces asthma-like Th2-mediated lung injury through IL-33 secretion
Researchers found that inhaled polystyrene microplastic particles triggered asthma-like inflammation in the lungs of mice, with smaller particles causing more severe responses. The particles stimulated the release of IL-33, a signaling molecule that activates a specific type of immune response associated with allergic airway disease. The study identifies a potential mechanism by which airborne microplastics could contribute to respiratory inflammation.
Action mechanism as a cause of chronic constipation of inhaled and intravenously injected polystyrene nanoplastics in ICR mice
Researchers found that ICR mice inhaling 500 nm polystyrene nanoplastics for two weeks developed significant constipation symptoms — reduced GI motility, altered mucin secretion, and enteric nervous system disruption — demonstrating that inhaled nanoplastics can affect gut function.
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.
Polystyrene micro- and nanoparticles exposure induced anxiety-like behaviors, gut microbiota dysbiosis and metabolism disorder in adult mice
A mouse study found that exposure to both micro- and nano-sized polystyrene particles caused anxiety-like behavior, disrupted gut bacteria, and altered metabolism. The nanoplastics caused more severe effects than the larger microplastics, and longer exposure periods made the damage worse. These findings support the idea that plastic particles can affect brain function and behavior through the gut-brain connection.
Polystyrene nanoplastics aggravate house dust mite induced allergic airway inflammation through EGFR/ERK-dependent lung epithelial barrier dysfunction
In mice with allergic asthma triggered by house dust mites, exposure to polystyrene nanoplastics significantly worsened airway inflammation and lung damage. The nanoplastics disrupted the protective barrier of lung cells by activating a specific signaling pathway (EGFR/ERK), allowing more allergens and immune cells to penetrate lung tissue. This finding suggests that airborne nanoplastics could make asthma and allergies worse for the millions of people who already suffer from these conditions.
Differently surface-labeled polystyrene nanoplastics at an environmentally relevant concentration induced Crohn’s ileitis-like features via triggering intestinal epithelial cell necroptosis
Researchers found that polystyrene nanoplastics at environmentally realistic levels triggered Crohn's disease-like inflammation in the small intestine of mice. Different surface coatings on the nanoplastics affected which immune pathways were activated, but all types caused gut damage. This study suggests that nanoplastic exposure through food and water could contribute to inflammatory bowel disease in humans.
Intergenerational neurotoxicity of polystyrene nanoplastics in offspring mice is mediated by dysfunctional microbe-gut-brain axis
Researchers found that mother mice exposed to polystyrene nanoplastics during pregnancy and nursing passed neurological harm to their offspring, with the babies showing brain inflammation, disrupted dopamine and serotonin signaling, and gut microbiome imbalances — suggesting that nanoplastic exposure before birth can damage the developing brain through the gut-brain connection.
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.
Mechanisms and therapeutics of immunometabolic reprogramming driving macrophage-ECs interactions in sepsis-associated ARDS from the gut-lung axis perspective
This review examines immunometabolic reprogramming mechanisms in sepsis-associated acute respiratory distress syndrome from the perspective of the gut-lung axis. While not directly about microplastics, the research explores immune pathways and gut-lung interactions that are relevant to understanding how environmental pollutants including microplastics may affect inflammatory responses. The study provides context on the biological mechanisms through which gut-derived signals can influence lung inflammation and immune cell function.
Gut Microbiota and Extraintestinal Disorders: Are They Interrelated?
This review examines how disturbances to the gut microbiome — the community of bacteria living in the digestive tract — are linked not just to intestinal diseases but also to allergies, asthma, and cardiovascular conditions. This context is relevant to microplastics research because ingested plastic particles have been shown to alter gut microbial communities.
Breathing plastics: Influence of airborne microplastics on the respiratory microbiome and health of human lungs (Review)
Researchers reviewed evidence showing that inhaled airborne microplastics can physically interact with the microbial community living in human lungs, disrupting its balance and triggering inflammation linked to conditions like asthma and fibrosis. Because microplastic particles have been found in lung tissue and fluid samples, inhalation is now recognized as a significant exposure route with measurable consequences for respiratory health.