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61,005 resultsShowing papers similar to Bioaccumulation of differently-sized polystyrene nanoplastics by human lung and intestine cells
ClearCellular internalization and release of polystyrene microplastics and nanoplastics
Scientists studied how polystyrene plastic particles of different sizes enter and exit living cells. They found that particles 50 and 500 nanometers in size can penetrate cell membranes and get taken up through multiple pathways, while 5-micrometer particles are too large to enter cells. This research helps explain why smaller nanoplastics may be more harmful to human health, as they can more easily get inside our cells and accumulate there.
Correlation between cellular uptake and cytotoxicity of polystyrene micro/nanoplastics in HeLa cells: A size-dependent matter
Researchers tested polystyrene particles of various sizes on human cells and found that only the smallest nanoplastics, those under about 25 nanometers in radius, could enter cells and cause toxic effects. Larger microplastic particles did not penetrate the cell membrane and showed no toxicity even at very high concentrations. The study provides a clear explanation for why smaller plastic particles tend to be more harmful, directly linking cell entry to cellular damage.
Effects of bisphenol A and nanoscale and microscale polystyrene plastic exposure on particle uptake and toxicity in human Caco-2 cells
Researchers studied how human intestinal Caco-2 cells take up polystyrene plastic particles of five different sizes ranging from 300 nanometers to 6 micrometers. The study found that smaller particles were taken up at higher rates and that co-exposure with bisphenol A increased cellular toxicity, suggesting that nanoscale plastics may pose a greater risk to human intestinal cells than larger microplastics.
Endocytosis, Distribution, and Exocytosis of Polystyrene Nanoparticles in Human Lung Cells
Researchers studied how polystyrene nanoparticles of 50 and 100 nanometers enter and exit human lung cells. They found that cellular uptake increased with exposure time and dose, with the smaller particles being taken up more readily and primarily accumulating in lysosomes. The study reveals that while lung cells can expel some ingested nanoplastics, a significant portion remains inside the cells, raising concerns about long-term respiratory exposure.
Cellular interactions with polystyrene nanoplastics—The role of particle size and protein corona
Researchers investigated how polystyrene nanoplastics interact with mammalian cells, finding that particle size and the protein corona that forms around particles in biological fluids strongly influence cellular uptake and toxicity. Smaller nanoplastics penetrated cell membranes more readily and caused greater disruption, suggesting that the tiniest plastic particles may pose the greatest biological risk.
The potential effects of microplastic pollution on human digestive tract cells
Researchers tested polystyrene particles of four different sizes on human colon and small intestine cells to assess the potential effects of microplastic ingestion. They found that the smallest nanoscale particles were more readily taken up by cells and caused greater reductions in cell viability and increased oxidative stress. The study suggests that smaller plastic particles may pose a greater risk to the human digestive tract than larger ones.
The internal dose makes the poison: higher internalization of polystyrene particles induce increased perturbation of macrophages
Researchers exposed human macrophages, key immune cells, to polystyrene particles of different sizes and found that smaller particles were internalized more readily and caused greater cellular disruption. Nanoscale plastics triggered stronger inflammatory responses and more oxidative stress than larger microplastics. The study suggests that the amount of plastic actually absorbed by immune cells, not just the amount present in the environment, determines how harmful the exposure is.
Nano-plastics and gastric health: Decoding the cytotoxic mechanisms of polystyrene nano-plastics size
Researchers examined how different sizes of polystyrene nanoplastics affect human stomach cells in the laboratory. They found that smaller nanoplastics were more readily taken up by the cells and caused greater damage, including increased oxidative stress and reduced cell survival. The study suggests that nanoplastic particle size plays a critical role in determining their potential impact on gastrointestinal health.
Cell uptake of mixtures of different-sized nanoplastics: Interplay and mechanism
Researchers studied how two sizes of polystyrene nanoplastics interact during cellular uptake, finding that larger 100 nm particles can pull smaller 50 nm particles into cells via clathrin-mediated endocytosis, while smaller particles alter the protein corona of larger ones in serum, either enhancing or inhibiting uptake depending on concentration ratios.
Uptake and toxicity of polystyrene micro/nanoplastics in gastric cells: Effects of particle size and surface functionalization
Researchers evaluated the uptake and toxicity of polystyrene micro- and nanoplastics in human gastric cells, comparing different sizes and surface treatments. The study found that smaller 50-nanometer particles were taken up at significantly higher rates, with positively charged aminated particles being the most toxic, causing cytotoxicity at lower concentrations and higher rates of cell death.
Effects of polystyrene micro/nanoplastics on liver cells based on particle size, surface functionalization, concentration and exposure period
Researchers systematically studied the effects of polystyrene micro- and nanoplastics on human liver cells, varying particle size, surface chemistry, concentration, and exposure duration. They found that smaller particles were internalized more readily and that surface functionalization significantly influenced toxicity, with aminated particles causing the most cell damage. The study suggests that particle characteristics beyond just size play an important role in determining how micro- and nanoplastics affect human cells.
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.
Internalization and toxicity: A preliminary study of effects of nanoplastic particles on human lung epithelial cell
Researchers studied the effects of polystyrene nanoplastic particles on human lung cells and found that the particles were internalized by the cells and caused dose-dependent toxicity. The nanoplastics triggered oxidative stress, inflammation, and disrupted normal cell function. The findings suggest that inhaling airborne nanoplastics may pose risks to respiratory health.
Size-dependent effects of polystyrene nanoplastics on autophagy response in human umbilical vein endothelial cells
Researchers studied how polystyrene nanoplastics of two different sizes affect human umbilical vein endothelial cells, focusing on a cellular cleanup process called autophagy. They found that smaller nanoplastics were taken up by cells more readily and caused greater disruption to autophagy function than larger particles. The study suggests that nanoplastic size is a critical factor in determining cardiovascular health risks, as these particles can impair the cells lining blood vessels.
Defining the size ranges of polystyrene nanoplastics according to their ability to cross biological barriers
Researchers systematically examined polystyrene nanoplastics of different sizes to define the size ranges at which they can cross biological barriers, providing a more precise definition of nanoplastic dimensions relevant to toxicological assessment.
Uptake and Toxicity of Polystyrene NPs in Three Human Cell Lines
Researchers tested three sizes of polystyrene nanoparticles on human gut and liver cell lines and found that smaller particles (30 nm) were more toxic than larger ones (100 nm). Despite significant uptake by all cell types, the overall toxicity was low at tested concentrations. Interestingly, the nanoparticles entered cells mainly through a scavenger receptor pathway rather than the commonly assumed routes, which could change how scientists predict nanoplastic behavior in the human body.
Multi-endpoint toxicological assessment of polystyrene nano- and microparticles in different biological models in vitro
Researchers assessed the toxicity and transport of polystyrene nano- and microparticles using multiple human cell models, including intestinal and placental barrier systems. They found that while neither size was acutely toxic, the nanoparticles were able to cross the intestinal barrier and showed some embryotoxic potential. The study suggests that nanoplastics may pose greater health concerns than microplastics due to their ability to penetrate biological barriers.
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.
Biological interactions of polystyrene nanoplastics: Their cytotoxic and immunotoxic effects on the hepatic and enteric systems
Researchers exposed mouse and human liver cells and live mice to polystyrene nanoplastics of five different sizes and found that the smallest particles were most toxic in lab dishes, while medium and large particles caused the most liver damage in living animals. The larger particles triggered immune responses by recruiting inflammatory cells to the liver and intestines, causing tissue damage. This study reveals that nanoplastic size matters in unexpected ways, and that lab tests alone may not predict which particles are most dangerous in the body.
Nanoplastics as a potential environmental health factor: effects of polystyrene nanoparticles on human intestinal epithelial Caco-2 cells
Researchers tested how polystyrene nanoparticles interact with human intestinal cells in the lab. They found that the nanoparticles were readily taken up by the cells in a concentration-dependent manner, but no significant toxic effects were observed under the conditions tested. The study suggests that while nanoplastics can enter gut cells, their short-term toxicity at the tested levels appears limited.
Size-dependent translocation of polystyrene nanoplastics across biological barriers in mammals
This study tracked radiolabeled nanoplastic particles in rats and found that smaller 20-nanometer particles could cross biological barriers that larger 100-nanometer particles could not, including reaching the brain. Both sizes were transferred from mothers to offspring, but through different pathways, revealing that nanoplastic size plays a critical role in determining which organs and tissues are exposed.
Elucidating the Size‐Dependency of In Vitro Digested Polystyrene Microplastics on Human Intestinal Cells Health and Function
Polystyrene microplastics of different sizes were subjected to simulated in vitro digestion and then applied to human intestinal cells, with smaller particles causing greater disruption to cell health and barrier function than larger ones. The results suggest that the smallest microplastics reaching the human gut pose the greatest risk to intestinal integrity.
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.
Size-dependent and tissue specific accumulation of polystyrene microplastics and nanoplastics in zebrafish
Researchers tracked size-dependent accumulation of polystyrene micro- and nanoplastics in multiple zebrafish tissues, finding that smaller particles distributed more broadly throughout the body compared to larger ones. Nanoplastics showed greater systemic distribution including into brain and reproductive tissues, raising concerns about size-dependent health risks.