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61,005 resultsShowing papers similar to Blood uptake and urine excretion of nano- and micro-plastics after a single exposure.
ClearEvidence on Invasion of Blood, Adipose Tissues, Nervous System and Reproductive System of Mice After a Single Oral Exposure: Nanoplastics versus Microplastics.
Researchers found that after a single oral exposure in mice, nanoplastics were rapidly absorbed into the blood, accumulated in fat tissues, and crossed both the blood-brain and blood-testis barriers. The study demonstrated that the distribution and behavior of plastic particles in mammals is strongly dependent on particle size, with nanoplastics showing substantially greater tissue penetration than microplastics.
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.
The Uptake and Distribution Evidence of Nano- and Microplastics in vivo after a Single High Dose of Oral Exposure.
This in vivo study provided evidence on the uptake and organ distribution of nano- and microplastics following a single high-dose administration, finding that nanoplastics translocated rapidly to multiple organs through blood circulation while only small amounts of larger microplastics penetrated organs.
Crossing barriers – tracking micro- and nanoplastic pathways into the human brain
Researchers tracked potential pathways by which micro- and nanoplastics may enter the human brain, examining both in vitro cell models and post-mortem brain tissue. They found that human monocytes rapidly internalized polystyrene particles into endocytic vesicles and mitochondria, and detected plastic particles in brain tissue samples, providing evidence that nanoplastics may be capable of crossing brain barriers.
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.
Systemic effects of nanoplastics on multi-organ at the environmentally relevant dose: The insights in physiological, histological, and oxidative damages
Researchers gave mice nanoplastics at doses estimated to match real-world human exposure levels and found the particles crossed the intestinal barrier and accumulated in the liver and kidneys. Even at these low, environmentally relevant doses, the nanoplastics caused oxidative stress and tissue damage across multiple organs. The findings suggest that everyday nanoplastic exposure may pose broader health risks than previously assumed.
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.
Orally administered fluorescent nanosized polystyrene particles affect cell viability, hormonal and inflammatory profile, and behavior in treated mice
Researchers found that orally administered fluorescent polystyrene nanoparticles passed through the mouse digestive system and accumulated in multiple organs. The study observed changes in cell viability, hormonal and inflammatory profiles, and behavior in treated mice, providing evidence that ingested nanoplastics can cross biological barriers and affect multiple body systems.
Tissue Distribution of Polystyrene or Mixed Polymer Microspheres and Metabolomic Analysis after Oral Exposure in Mice.
Mice orally exposed to polystyrene or mixed polymer microspheres showed plastic particle distribution across multiple tissues including the liver, kidney, and spleen, with metabolomic analysis revealing distinct alterations in lipid, amino acid, and energy metabolism pathways.
Penetration of micro/nanoplastics into biological barriers in organisms and associated health effects
This Chinese-language review systematically examined how micro- and nanoplastics penetrate gastrointestinal, respiratory, and skin barriers in humans and model organisms, and how they translocate via blood circulation to accumulate in organs including the liver, brain, testes, and placenta.
Micro- and nanoplastics: origin, sources of intake and impact on human health (literature review)
This literature review synthesizes mechanisms by which micro- and nanoplastics interact with living organisms, examining their physicochemical properties, routes of human exposure, and documented health effects across multiple organ systems.
A review on micro- and nanoplastics in humans: Implication for their translocation of barriers and potential health effects
This review compiles evidence showing that micro- and nanoplastics have been found in human blood, lungs, placenta, and other organs, and can cross protective barriers including the blood-brain and placental barriers. The accumulated evidence links these particles to inflammation, oxidative stress, hormone disruption, and potential effects on reproduction and brain health, though more research is needed to determine exact risk levels.
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.
A new insight of size-dependent plastics particles kinetics with regarding of metabolomics effects in liver and kidney
Researchers developed a comprehensive extraction and detection protocol to track polystyrene particles of three sizes (80 nm, 2 µm, and 20 µm) across multiple organs in exposed animals, finding that smaller particles accumulated more broadly — reaching the brain, liver, spleen, and kidney — while liver and kidney metabolism was disrupted in size-dependent but distinct ways.
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.
Micro- and Nanoplastics on Human Health and Diseases: Perspectives and Recent Advances
This review provides a comprehensive overview of how micro- and nanoplastics enter the human body through ingestion, inhalation, and skin absorption, and how they can then travel through the bloodstream to reach virtually every organ. Researchers summarize evidence that these particles can trigger inflammation, oxidative stress, and disruption of hormonal and immune functions. The study emphasizes that the ability of these particles to cross biological barriers and accumulate in tissues makes understanding their long-term health effects an urgent research priority.
Size-Dependent PulmonaryToxicity and Whole-Body Distributionof Inhaled Micro/Nanoplastic Particles in Male Mice from Chronic Exposure
Researchers used a whole-body inhalation exposure system to chronically expose male mice to polystyrene micro- and nanoplastics at environmental concentrations and tracked particle distribution and lung toxicity. Nanoplastics (80 nm) showed greater tissue transport than microplastics (1 µm), with highest accumulation in lungs followed by blood and spleen, and both sizes disrupted oxidative balance and antioxidant defenses.
Ingested nano- and microsized polystyrene particles surpass the intestinal barrier and accumulate in the body
Researchers fed mice nano- and microsized polystyrene particles for up to 24 weeks to study intestinal barrier crossing and accumulation. The study found that plastic particles accumulated in the small intestine and distant organs, though they did not promote intestinal inflammation or worsen colitis, while noting that long-term accumulative effects on gastrointestinal health cannot be ruled out.
Tissue distribution of polystyrene nanoplastics in mice and their entry, transport, and cytotoxicity to GES-1 cells
Scientists tracked polystyrene nanoplastics in mice after oral exposure and found the particles accumulated in the stomach, intestines, and liver tissues. In human gastric cells, the nanoplastics entered through multiple pathways and were transported through the cell's internal trafficking system, ultimately reducing cell growth and increasing cell death. The study provides detailed evidence of how nanoplastics can cross biological barriers and cause cellular damage in mammalian systems.
Why Detecting Nanoplastics in Humans Matters: Exposure Routes, Biological Evidence, and Potential Health Implications
This review summarizes current evidence on nanoplastic detection in human biological samples, including blood, lung tissue, placenta, and brain samples, confirming that human exposure involves internal uptake rather than just environmental contact. The study discusses how ingestion and inhalation are the dominant exposure pathways, while experimental research suggests nanoplastics may induce oxidative stress, inflammation, and endocrine disruption, though direct causal links in humans remain limited.
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.
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.
In vivo impact assessment of orally administered polystyrene nanoplastics: biodistribution, toxicity, and inflammatory response in mice
Researchers orally administered polystyrene nanoplastics to mice for two weeks and tracked their distribution and biological effects. The nanoplastics accumulated primarily in the intestine, kidneys, and liver, triggering significant inflammatory responses and oxidative stress in these organs despite no visible tissue damage. The study provides evidence that even short-term oral exposure to nanoplastics can cause meaningful inflammatory changes in multiple organ systems.
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.