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20 resultsShowing papers similar to Size-Dependent PulmonaryToxicity and Whole-Body Distributionof Inhaled Micro/Nanoplastic Particles in Male Mice from Chronic Exposure
ClearSize-Dependent Pulmonary Toxicity and Whole-Body Distribution of Inhaled Micro/Nanoplastic Particles in Male Mice from Chronic Exposure
Researchers exposed mice to airborne micro- and nanoplastic particles through normal breathing over an extended period and found the highest accumulation in the lungs, followed by the blood and spleen. Surprisingly, the larger 1-micrometer microplastics caused more severe lung damage than the smaller 80-nanometer particles, triggering inflammation, cell death, and scarring. These findings highlight that breathing in airborne plastic particles poses real health risks, with particle size playing an important role in the type of damage caused.
Analysis of Biodistribution and in vivo Toxicity of Varying Sized Polystyrene Micro and Nanoplastics in Mice
This study found that smaller plastic particles spread more widely through the bodies of mice and caused more organ damage than larger ones, particularly in the liver, kidneys, and heart. Nanoplastics (under 1 micrometer) were especially concerning because they crossed biological barriers more easily than microplastics. The results suggest that the tiniest plastic particles in our environment may pose the greatest health risks.
Comparison of PET tracing and biodistribution between 64Cu-labeled micro-and nano-polystyrene in a murine inhalation model
Using advanced PET imaging in mice, researchers tracked where inhaled micro and nanoplastics traveled in the body and found that nano-sized particles cleared from the lungs much faster than micro-sized ones but accumulated more in the liver, spleen, and other organs. Micro-sized particles stayed in the lungs longer, with peak retention at 24 hours, while nano-sized particles spread quickly throughout the body. This is one of the first studies to directly visualize how inhaled plastic particles distribute through living mammals, confirming that smaller particles pose a greater risk of reaching organs beyond the lungs.
Comparison of PET tracing and biodistribution between 64Cu-labeled micro-and nano-polystyrene in a murine inhalation model
Using radioactive copper labeling and PET imaging, researchers tracked where inhaled micro- and nano-sized polystyrene particles travel in the body, finding that nanoplastics distributed more widely to organs than microplastics after lung exposure. This is significant for understanding the health risks of airborne plastic particles, which people inhale daily from synthetic textiles, dust, and urban air.
Tissue accumulation of microplastics in mice and biomarker responses suggest widespread health risks of exposure
Researchers fed mice polystyrene microplastics of two sizes and tracked where the particles accumulated in the body, finding them in the liver, kidneys, and gut with distribution patterns depending on particle size. Biochemical analysis revealed that microplastic exposure disrupted energy and fat metabolism, caused oxidative stress, and altered markers of neurotoxicity in the blood. The study provides evidence that microplastics can accumulate in mammalian tissues and may pose widespread health risks.
Microplastics and nanoplastics, emerging pollutants, increased the risk of pulmonary fibrosis in vivo and in vitro: A comparative evaluation of their potential toxicity effects with different polymers and size
Researchers compared the lung toxicity of microplastics and nanoplastics made from polystyrene, polyethylene, and polypropylene in mice and human lung cells. They found that all particle types induced signs of pulmonary fibrosis, inflammation, and tissue remodeling, with polystyrene nanoplastics causing the most severe effects. The study suggests that smaller nanoplastic particles and certain polymer types may pose greater risks to lung health.
Systematic toxicity evaluation of polystyrene nanoplastics on mice and molecular mechanism investigation about their internalization into Caco-2 cells
Researchers fed mice polystyrene nanoplastics (about 100 nm) for 28 days and found the particles accumulated in multiple organs including the spleen, lungs, kidneys, intestines, testes, and brain. The nanoplastics caused cell death, inflammation, and tissue damage in these organs, as well as disrupted fat metabolism and blood cell counts. This study demonstrates that ingested nanoplastics can spread throughout the body and cause widespread harm, raising concerns about long-term human exposure.
In vivo toxicity assessment of microplastics in Balb/C mice : study of inhalation exposure and its inflammatory effects
Researchers examined the in vivo toxicity of inhaled microplastics in Balb/C mice, studying pulmonary inflammation, oxidative stress, and systemic effects following repeated inhalation exposure. The study found dose-dependent lung inflammation and evidence of particle translocation to other organs.
Size-dependent toxicity of polystyrene microplastics in lung cells: An in vivo and in vitro study
Researchers investigated the size-dependent toxicity of polystyrene microplastics in lung cells using both mouse and cell culture models. The study found that smaller 1-micrometer particles accumulated more in lung tissue than larger particles and identified epithelial-mesenchymal transition as a key toxic mechanism, driven by ECM-MMP signaling cascades that contribute to lung injury.
Deleterious effects of microplastics and nanoplastics on rodent lungs: a systematic review
This systematic review summarizes research on how inhaled micro- and nanoplastics affect the lungs in animal studies. The findings show these particles can cause lung inflammation, tissue damage, and immune responses, suggesting that breathing in airborne microplastics may pose real risks to respiratory health.
Size-dependent internalization of polystyrene microplastics as a key factor in macrophages and systemic toxicity
Researchers systematically tested how the size of polystyrene microplastics affects their uptake and toxicity in immune cells and mice. Smaller particles (0.5 micrometers) were taken up much more readily by immune cells and caused more damage, including mitochondrial dysfunction and cell death, compared to larger 5-micrometer particles. In living mice, smaller microplastics accumulated more in organs and caused broader changes in blood and metabolic markers, confirming that particle size is a key factor in microplastic toxicity.
Lung retention, distribution and persistence of polymer particles in rats exposed via inhalation
Researchers studied the fate of inhaled polymer particles in rats by exposing them to polystyrene and polyamide aerosols for 28 days. The study found that both types of particles accumulated in the lungs and migrated to lung-draining lymph nodes, but were not detected in the liver, spleen, or kidneys. The particles persisted in lung tissue for weeks after exposure ended, raising questions about the long-term bioavailability and fate of inhaled microplastics.
Blood uptake and urine excretion of nano- and micro-plastics after a single exposure.
Mice exposed to polystyrene nanoparticles (100 nm) and microparticles (3 µm) via different routes showed that smaller particles appeared rapidly in blood and were detected in urine, while larger particles cleared more slowly. The study provides direct evidence that nanoplastics can cross biological barriers and enter circulation, with potential for distribution throughout the body.
Nanopolystyrene Translocation and Fetal Deposition After Acute Lung Exposure During Late-Stage Pregnancy
Nanopolystyrene particles inhaled by pregnant mice during late pregnancy crossed into the bloodstream and deposited in fetal tissues. This finding raises concern that airborne nanoplastics could pose a risk to fetal development, especially given growing human exposure to plastic particles in indoor and outdoor air.
Lung retention, distribution and persistence of polymer particles in rats exposed via inhalation
Researchers studied the fate of inhaled polymer particles in rats by exposing them to polystyrene and polyamide aerosols for 28 days. The study found that both types of particles accumulated in the lungs and migrated to lung-draining lymph nodes, but were not detected in the liver, spleen, or kidneys. The particles persisted in lung tissue for weeks after exposure ended, highlighting potential concerns about long-term retention of inhaled microplastics.
Repeated inhalation exposure to polystyrene nanoplastics induced sustained pulmonary injury and fibrosis in mice.
Scientists exposed mice to tiny plastic particles found in air pollution and discovered these particles caused serious lung damage and scarring that didn't heal even weeks after exposure stopped. The smallest plastic particles were the most harmful, spreading from the lungs to other organs like the heart and liver. This research suggests that breathing in nanoplastics from everyday sources like car tire wear and plastic waste could pose long-term risks to human lung health.
Inhalation toxicity of polystyrene micro(nano)plastics using modified OECD TG 412
Researchers conducted inhalation toxicity testing of polystyrene micro- and nanoplastics in rats using a modified OECD standard protocol. They found that inhaled plastic particles caused inflammatory responses in lung tissue and were detected in various organs, indicating systemic distribution after inhalation. The study provides important regulatory-relevant data suggesting that airborne microplastics pose measurable inhalation health risks.
Unveiling the Pulmonary Toxicity of Polystyrene Nanoplastics: A Hierarchical Oxidative Stress Mechanism Driving Acute–Subacute Lung Injury
Researchers investigated the pulmonary toxicity of polystyrene nanoplastics smaller than 100 nm in lung epithelial cells and macrophages, finding that exposure triggered a hierarchical oxidative stress mechanism that drove acute to subacute lung injury through lipid peroxidation and inflammation.
Inhaled polystyrene nanoparticles may cause fibrotic lesions via immune dysregulation and energy metabolism disturbance
Mice received polystyrene nanoparticles via pharyngeal instillation for 90 days and were assessed for local lung and systemic toxicity. The nanoparticles accumulated in lungs and hearts, caused immune dysregulation, disrupted energy metabolism, and induced fibrotic lesions at higher doses, suggesting that chronic inhalation of nanoplastics may contribute to pulmonary fibrosis.
Nanopolystyrene translocation and fetal deposition after acute lung exposure during late-stage pregnancy
Researchers exposed pregnant mice to nanoscale polystyrene particles through inhalation and tracked where the particles traveled. They found that the nanoplastics crossed from the lungs into the bloodstream and accumulated in both placental and fetal tissues, confirming that inhaled plastic nanoparticles can reach developing offspring during pregnancy.