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61,005 resultsShowing papers similar to Human neurons are susceptible to the internalization of small-sized nanoplastics
ClearCrossing 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.
Internalization and toxicity of polystyrene nanoplastics on inmortalized human neural stem cells
Researchers tested 30-nanometer polystyrene particles on human neural stem cells grown in the lab and found the particles entered the cells, accumulated inside them, and triggered cell death. The nanoplastics also slowed cell growth but did not penetrate the cell nucleus. This study provides direct evidence that nanoplastics could harm the brain's stem cells, raising concerns about potential effects on brain development.
Cellular 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.
Polystyrene nanoplastics penetrate across the blood-brain barrier and induce activation of microglia in the brain of mice
Researchers demonstrated that 50-nanometer polystyrene nanoplastics can cross the blood-brain barrier in mice, accumulate in brain tissue, and activate immune cells called microglia that then damage neurons. The nanoplastics disrupted the tight junctions that normally protect the brain, creating openings for the particles to pass through. This study provides direct evidence that nanoplastics can reach the brain and trigger inflammation, raising concerns about potential neurological effects of long-term nanoplastic exposure in humans.
Polystyrene Micro- and Nanoplastic Exposure Triggers an Activation and Stress Response in Human Astrocytes
Researchers exposed primary human astrocytes to polystyrene micro- and nanoplastics and found that these particles triggered cellular stress responses, including increased production of reactive oxygen species and activation of inflammatory pathways. Nanoplastics were particularly effective at penetrating cells and disrupting normal astrocyte function. The findings suggest that plastic particle exposure may contribute to neuroinflammatory processes in the brain, warranting further investigation into potential neurotoxic effects.
Molecular effects of polystyrene nanoplastics on human neural stem cells
Researchers exposed human brain stem cells to tiny polystyrene nanoplastics and found they caused oxidative stress, DNA damage, inflammation, and cell death. These findings suggest that nanoplastics could potentially harm brain development if they reach neural tissue, though more research is needed to understand real-world exposure levels.
Polystyrene nanoplastics modulate neurite length in a size-specific manner
Researchers exposed primary neurons to polystyrene nanoplastics of three different sizes (50, 100, and 250 nm) at low concentrations to evaluate effects on brain cell development. The study found that nanoplastics modulate neurite length in a size-specific manner, suggesting that even short, low-dose exposures to plastic nanoparticles may affect neuronal growth and connectivity.
Neurotoxic potential of polystyrene nanoplastics in primary cells originating from mouse brain
Researchers exposed three types of primary mouse brain cells to 100 nm polystyrene nanoplastics and found that neurons underwent apoptosis while astrocytes survived but developed reactive astrocytosis with elevated inflammatory markers, suggesting that neuronal vulnerability to nanoplastic accumulation may be amplified by astrocyte-driven neuroinflammation.
Brain under siege: the role of micro and nanoplastics in neuroinflammation and oxidative stress
This review examines emerging evidence that micro- and nanoplastics can cross the blood-brain barrier and accumulate in nervous tissue, potentially triggering neuroinflammation and oxidative stress. Researchers summarized findings showing these particles may act as neurotoxicants that contribute to synaptic dysfunction and pathological changes in brain cells. The study highlights the need for further research into how chronic plastic particle exposure may affect central nervous system health over time.
Polystyrene nanoplastics exposure caused defective neural tube morphogenesis through caveolae-mediated endocytosis and faulty apoptosis
This study found that polystyrene nanoplastics caused abnormal neural tube formation in early embryonic development by being taken up through a specific cellular pathway and triggering defective cell death. The findings suggest nanoplastics could potentially interfere with fetal brain development, raising serious concerns about exposure during pregnancy.
Bioaccumulation of differently-sized polystyrene nanoplastics by human lung and intestine cells
Researchers examined how human lung and intestine cells take up polystyrene nanoplastics of different sizes, finding that smaller particles were internalized in greater numbers but at lower total mass compared to larger ones. When compared on a surface area basis, the uptake rates were similar across sizes, suggesting that surface interactions with cell membranes play a key role. The findings indicate that particle size is an important factor to consider when evaluating the health risks of nanoplastic exposure.
Primary astrocytes as a cellular depot of polystyrene nanoparticles
Researchers found that astrocytes — support cells in the brain — absorb polystyrene nanoplastics far more efficiently than neurons and act as a cellular buffer to protect nerve cells, but become overactivated when the particle load is too high, losing their protective function and potentially contributing to neurological harm.
Size-dependent neurotoxicity of micro- and nanoplastics in flowing condition based on an in vitro microfluidic study
Researchers studied the size-dependent neurotoxicity of polystyrene micro- and nanoparticles on mouse hippocampal neuronal cells using a microfluidic system that simulates flowing conditions. The study found that both particle sizes were efficiently taken up by cells, but nanoparticles showed greater neurotoxic effects at the concentrations tested. Evidence indicates that particle size is an important factor in determining the neurological impact of plastic pollution.
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.
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.
The neurotoxic threat of micro- and nanoplastics: evidence from In Vitro and In Vivo models
This systematic review examined 26 studies showing that micro- and nanoplastics can cross into the brain, damage neurons, and trigger inflammation in lab and animal models. These findings raise concerns that long-term plastic exposure could contribute to neurological problems in humans, though more research is needed.
Effects of Polystyrene Nanoplastics on the Biology of Human Neural Stem Cells and Human Cerebral Organoids.
This study investigated the effects of polystyrene nanoplastics on human neural stem cells and human cerebral organoids, examining whether nanoplastics that have been shown to cross the blood-brain barrier and placenta can disrupt normal brain development. Given the lack of prior research on nanoplastic effects on the developing brain, the findings carry significant implications for understanding neurodevelopmental risks from early-life plastic exposure.
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.
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.
Microplastics/nanoplastics and neurological health: An overview of neurological defects and mechanisms
This review summarizes evidence that micro and nanoplastics can harm the nervous system, causing developmental abnormalities, brain cell death, neurological inflammation, and potentially contributing to neurodegenerative diseases. Animal studies show that these tiny plastics can cross the blood-brain barrier and accumulate in brain tissue, where they trigger oxidative stress and disrupt normal brain function. While direct evidence in humans is still limited, the findings suggest that chronic microplastic exposure could be a risk factor for neurological health problems.
Impact of micro- and nanoplastics exposure on human health: focus on neurological effects from ingestion
This review compiles emerging evidence on how ingested microplastics and nanoplastics may affect the brain and nervous system. Researchers found that these particles can disrupt gut bacteria, cross the blood-brain barrier, and accumulate in neural tissue, potentially triggering inflammation, oxidative stress, and protein changes linked to cognitive problems. The study highlights an urgent need for more human research, as initial findings have associated elevated plastic particle levels in brain tissue with neurological concerns.
Neuronal damage induced by nanopolystyrene particles in nematodeCaenorhabditis elegans
C. elegans nematodes were chronically exposed to nanopolystyrene particles and found to develop neuronal damage affecting both development and function of the nervous system after long-term exposure at environmentally relevant concentrations. The study provides early evidence that nanoplastics can cause neurological harm in an animal model, raising questions about potential neurotoxicity in other species.
Alleviation of neurotoxicity induced by polystyrene nanoplastics by increased exocytosis from neurons
Researchers investigated how polystyrene nanoplastics accumulate in neurons and cause toxic effects on brain cells. They found that inhibiting a specific protein involved in transporting particles within cells promoted the export of nanoplastics from neurons, reducing their harmful effects. The study suggests that enhancing the cell's natural ability to expel nanoplastics could be a potential strategy for alleviating their neurotoxic impact.
Neurotoxicity of nanoplastics: A review
This review examines the growing body of evidence on how nanoplastics may affect the nervous system. Researchers summarized findings showing that nanoplastics can cross biological barriers, accumulate in brain tissue, and trigger oxidative stress and inflammation in nerve cells. The evidence indicates that nanoplastic exposure may contribute to neurotoxic effects, though more research is needed to fully understand the risks to human brain health.