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61,005 resultsShowing papers similar to Polystyrene Micro- and Nanoplastic Exposure Triggers an Activation and Stress Response in Human Astrocytes
ClearNeurotoxic 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.
Polystyrene Nano- and Microplastic Particles Induce an Inflammatory Gene Expression Profile in Rat Neural Stem Cell-Derived Astrocytes In Vitro
Researchers exposed brain cells derived from rat neural stem cells to polystyrene nano- and microplastics and found that astrocytes -- the most abundant brain support cells -- were the most affected, showing reduced survival and widespread changes in gene activity. The activated genes were involved in brain inflammation and immune responses, while genes for fat metabolism were turned down. These findings suggest that plastic particles reaching the brain could trigger inflammation that may contribute to neurological problems.
Exposure to microplastics/ nanoplastics induces responses of microglia and astrocytes: roles of oxidative stress and autophagy
This study examined how microplastic and nanoplastic exposure affects glial cells in the central nervous system, specifically investigating responses of microglia and astrocytes, which are the brain's primary immune and support cells. Results showed that micro- and nanoplastic exposure triggered inflammatory-type responses in these cells, raising concern for neurological effects.
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.
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.
Exposure to microplastics/ nanoplastics induces responses of microglia and astrocytes: roles of oxidative stress and autophagy
This study investigated how microplastic and nanoplastic exposure affects glial cells including microglia and astrocytes in the central nervous system, which are essential for neurological immune defense and homeostasis. Exposure triggered reactive responses in both cell types, raising concern that plastic particle accumulation in the brain could contribute to neuroinflammation.
Neurotoxic effects of polystyrene nanoplastics on memory and microglial activation: Insights from in vivo and in vitro studies
In a mouse study, tiny nanoplastics (30-50 nanometers) that were swallowed reached the brain and caused memory problems by activating the brain's immune cells, called microglia, which triggered inflammation. This is concerning because it shows that nanoplastics small enough to be found in everyday products like cosmetics could cross into the brain and impair cognitive function.
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.
Human neurons are susceptible to the internalization of small-sized nanoplastics
Researchers studied how human neurons take up nanoplastics and found that the cells readily absorbed 50-nanometer polystyrene particles through specific cellular pathways. The nanoplastics accumulated in cell compartments and, at higher concentrations, triggered oxidative stress and reduced cell survival. The study provides evidence that very small plastic particles can enter human brain cells, raising concerns about potential neurological effects of nanoplastic exposure.
Cytotoxicity and pro-inflammatory effect of polystyrene nano-plastic and micro-plastic on RAW264.7 cells.
Researchers found that polystyrene nano-plastics (80 nm) induced apoptosis and pro-inflammatory cytokine release in mouse macrophage RAW264.7 cells at lower concentrations than micro-plastics (3 μm), with nano-plastics also enhancing phagocytic activity and activating NF-kB signaling pathways more potently than their larger counterparts.
Unmasking the Invisible Threat: Biological Impacts and Mechanisms of Polystyrene Nanoplastics on Cells
This review summarizes how polystyrene nanoplastics, tiny plastic particles found throughout the environment, damage cells through multiple pathways including oxidative stress, DNA damage, inflammation, and mitochondrial dysfunction. Nanoplastics can trigger several forms of cell death and disrupt normal cell processes like autophagy (the cell's recycling system). The findings raise concerns about long-term human health effects from chronic exposure to these nearly invisible plastic particles.
Stress Response of Mouse Embryonic Fibroblasts Exposed to Polystyrene Nanoplastics
Mouse embryonic fibroblasts exposed to polystyrene nanoplastics internalized particles via endocytosis without losing viability, but showed activation of antioxidant and autophagic stress pathways, suggesting subcellular dysfunction even in the absence of cell death.
Disruption of cerebral cholesterol homeostasis by PS-NPs: astrocytic endoplasmic reticulum stress
Researchers found that polystyrene nanoplastics disrupt cholesterol production in brain support cells called astrocytes, which in turn prevents neurons from forming the connections needed for brain function. By triggering stress responses and blocking key cholesterol-making pathways, nanoplastics ultimately inhibit synapse formation — raising concerns about their potential role in neurological disease.
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.
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.
Effect of micro- and nanoplastic particles on human macrophages
This study is the first to visualize polystyrene micro- and nanoparticles inside primary human immune cells (macrophages) from actual blood donors, showing that the particles increase cell death and generate harmful reactive oxygen species. The findings provide direct evidence that human immune cells react to plastic particles in ways that could contribute to inflammation and health problems.
Evaluation of toxicity of polystyrene microplastics under realistic exposure levels in human vascular endothelial EA.hy926 cells
Researchers exposed human vascular endothelial cells to polystyrene microplastics at concentrations comparable to levels detected in human blood. They found that the microplastics caused oxidative stress, reduced antioxidant defenses, and triggered apoptosis in the vascular cells. The study suggests that microplastics circulating in the bloodstream at realistic concentrations may contribute to vascular damage by impairing cellular protective mechanisms.
Effects of exposure to micro/nanoplastics of polystyrene on neuronal oxidative stress, neuroinflammation, and anxiety-like behavior in mice: A Systematic Review
This systematic review examined 24 studies on how polystyrene microplastics and nanoplastics affect the brains of mice. The findings consistently showed that exposure led to increased oxidative stress, brain inflammation, and anxiety-like behavior. Maternal exposure also caused brain-related harm in offspring, suggesting these tiny plastic particles could pose real risks to the nervous system.
Inflammatory Effects of Microplastics and Nanoplastics on Nasal Airway Epithelial Cells
Researchers found that polystyrene micro- and nanoplastics cause inflammatory cytokine responses in nasal epithelial cells even over short exposure periods. The study also observed ciliary blunting and transcriptional evidence of significant inflammation and stress responses, suggesting that the nasal airway is vulnerable to plastic particle exposure.
Cerebral to SystemicRepresentations of Alzheimer’sPathogenesis Stimulated by Polystyrene Nanoplastics
Researchers exposed both wild-type and APP/PS1 Alzheimer's model mice to environmental levels of polystyrene nanoplastics and measured Alzheimer's-like pathology progression. Nanoplastics exacerbated cognitive decline, microglial activation, and hippocampal neuronal death, particularly in the Alzheimer's model, with systemic inflammatory effects suggesting plastic particles may accelerate neurodegeneration.
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.
Hazard Assessment of Polystyrene Nanoplastics in Primary Human Nasal Epithelial Cells, Focusing on the Autophagic Effects
Researchers exposed primary human nasal epithelial cells to polystyrene nanoplastics of two sizes and found that the smaller particles caused more significant cellular changes, including activation of autophagy pathways. The nanoplastics triggered oxidative stress and altered cell processes related to waste recycling within cells. The study highlights the potential health risks of inhaling airborne nanoplastics, an exposure route that remains understudied.
Exposure of microplastic at levels relevant for human health : cytotoxicity and cellular localization of polystyrene microparticles in four human cell lines
Researchers tested the cytotoxicity of polystyrene microplastics on four human cell lines at concentrations relevant to real-world human exposure from food, water, and packaging. At environmentally realistic doses, microplastics were taken up by cells but did not cause significant toxicity, though higher concentrations did produce cell damage, suggesting that current exposure levels may be near a threshold of concern.
Exploring toxicological pathways of microplastics and nanoplastics: Insights from animal and cellular models
This review examines what animal and cell studies have revealed about how microplastics and nanoplastics cause harm at the molecular level, including promoting inflammation, oxidative stress, and cell death. Most research has focused on reproductive toxicity and polystyrene particles, while effects on the gut, brain, and heart remain understudied. The authors note that many experiments use unrealistic concentrations and synthetic particles, making it difficult to apply the results to real-world human exposure.