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61,005 resultsShowing papers similar to Effects of polystyrene nanoplastic size on zebrafish embryo development
ClearPolystyrene nanoplastics induced size-dependent developmental and neurobehavioral toxicities in embryonic and juvenile zebrafish
Researchers exposed zebrafish embryos and juveniles to polystyrene nanoplastics of three different sizes and found that all sizes crossed into the brain, eyes, and other organs. Smaller particles tended to cause different types of damage than larger ones, including changes in brain development and behavior. This size-dependent toxicity is relevant to human health because we are exposed to a wide range of nanoplastic sizes through food and water.
Neurotoxicity of polystyrene nanoplastics with different particle sizes at environment-related concentrations on early zebrafish embryos
Researchers exposed zebrafish embryos to polystyrene nanoplastics of different sizes at concentrations found in the environment and observed significant brain damage. The nanoplastics caused loss of neurons, shortened nerve fibers, and disrupted brain signaling systems that control behavior. Smaller nanoplastics caused the most severe damage because they could pass through protective barriers more easily, suggesting that the tiniest plastic particles pose the greatest risk to brain development.
Evaluation of phenotypic and behavioral toxicity of micro- and nano-plastic polystyrene particles in larval zebrafish ( Danio rerio )
Researchers exposed larval zebrafish (Danio rerio) to six sizes (0.05–10.2 µm) and multiple concentrations of polystyrene micro/nanoplastics and assessed toxicity using embryo and behavioral assays. Smaller particles and higher concentrations caused greater phenotypic and behavioral toxicity, with particle uptake and organ distribution confirmed, establishing size as a key determinant of polystyrene MP toxicity in a vertebrate developmental model.
Microplastics induced developmental toxicity with microcirculation dysfunction in zebrafish embryos
Researchers exposed zebrafish embryos to polystyrene microplastics (1 micrometer) and nanoplastics (0.4 micrometer) to assess developmental toxicity. They found that nanoplastics caused significantly higher mortality and more severe microcirculation dysfunction than microplastics, despite being less visible in solution. The study indicates that smaller plastic particles may pose greater developmental risks to aquatic organisms during early life stages.
Polystyrene nanoplastics cause developmental abnormalities, oxidative damage and immune toxicity in early zebrafish development
Zebrafish embryos exposed to polystyrene nanoplastics showed dose-dependent developmental problems including delayed hatching, reduced survival, smaller body size, and the nanoplastics accumulated in critical organs like the eyes, heart, liver, and brain. The particles triggered oxidative stress that damaged cells and activated inflammatory immune responses, demonstrating how nanoplastic contamination in water can cause widespread harm to developing organisms.
Evaluation of phenotypic and behavioral toxicity of micro- and nano-plastic polystyrene particles in larval zebrafish (Danio rerio)
Researchers exposed zebrafish embryos to polystyrene particles ranging from 50 nanometers to 10 micrometers and found that nearly all sizes caused physical abnormalities and changes in swimming behavior. Smaller particles were taken up more readily and distributed to organs including the brain and gut. These findings are relevant to human health because zebrafish share many biological pathways with humans, and the results suggest that both micro- and nano-sized plastics can cause developmental harm.
Polystyrene Nanoplastic Exposure Adversely Affects Survivability of Zebrafish Larvae
Researchers found that polystyrene nanoplastic exposure significantly reduces survival rates of zebrafish larvae in a dose-dependent manner, documenting behavioral abnormalities and developmental defects that highlight the toxicity of nanoscale plastic particles to early vertebrate life.
Size matters: Zebrafish (Danio rerio) as a model to study toxicity of nanoplastics from cells to the whole organism
Researchers used zebrafish as a model organism to study the toxic effects of polystyrene nanoplastics at both cellular and whole-organism levels. They found that smaller nanoplastic particles were taken up more readily by cells and caused greater oxidative stress and developmental abnormalities than larger particles. The study confirms that particle size is a critical determinant of nanoplastic toxicity, with the smallest particles posing the greatest biological risks.
Polystyrene nanoplastics as an ecotoxicological hazard: cellular and transcriptomic evidences on marine and freshwater in vitro teleost models
Researchers tested the effects of two sizes of polystyrene nanoplastics on fish cell lines from both freshwater and marine species. They found that smaller 20-nanometer particles were significantly more toxic than larger 80-nanometer ones, causing cell death through apoptosis and disrupting multiple biological pathways. The study provides evidence that nanoplastic size is a key factor in determining toxicity to aquatic organisms.
Toxicological effects of nano- and micro-polystyrene plastics on red tilapia: Are larger plastic particles more harmless?
Researchers exposed red tilapia to three sizes of polystyrene particles (0.3, 5, and 70-90 micrometers) to compare their toxic effects. The study found that the largest particles showed the highest accumulation in tissues, but all sizes induced oxidative stress, disrupted cytochrome P450 enzymes, caused neurotoxicity, and altered metabolic profiles, indicating that even smaller nanoplastics can cause significant harm to fish.
Polystyrene microplastics effects on zebrafish embryological development: Comparison of two different sizes
Zebrafish embryos exposed to polystyrene microplastics of two different sizes (1 and 3 micrometers) showed increased heart rates, physical deformities, and cell death at higher concentrations. The microplastics accumulated inside the larvae and triggered oxidative stress, which is an imbalance that damages cells. These findings add to growing evidence that microplastics can interfere with early development in ways that may be relevant to understanding risks during human pregnancy and infancy.
Mechanisms Underlying the Size-Dependent Neurotoxicity of Polystyrene Nanoplastics in Zebrafish
Scientists discovered that smaller nanoplastics cause more severe brain and nerve damage in zebrafish than larger ones, and identified the molecular pathways behind this size-dependent toxicity. The smaller particles more easily crossed biological barriers and triggered greater oxidative stress and inflammation in the nervous system, which is important for understanding potential neurological risks of nanoplastic exposure.
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.
Polystyrene microplastics and nanoplastics induce neurotoxicity in zebrafish via oxidative stress and neurotransmitter disruption
Researchers exposed zebrafish embryos to polystyrene micro- and nanoplastics and found that both particle sizes caused neurodevelopmental toxicity, with nanoplastics being more potent. The plastic particles induced oxidative stress in the brain and disrupted neurotransmitter levels critical for normal neural development. The study suggests that microplastic and nanoplastic contamination in aquatic environments may pose significant risks to the neurological development of fish.
Uptake Routes and Biodistribution of Polystyrene Nanoplastics on Zebrafish Larvae and Toxic Effects on Development
Researchers exposed zebrafish embryos and larvae to amino-modified polystyrene nanoplastics to study uptake routes and biodistribution. The study found that nanoplastics accumulated in target organs and caused toxic developmental effects, providing evidence that these tiny plastic fragments can penetrate biological barriers and interfere with normal development in aquatic organisms.
Down to size: Exploring the influence of plastic particle Dimensions on physiological and nervous responses in early-stage zebrafish
Researchers compared the effects of microplastics versus nanoplastics on developing zebrafish and found that only the nanoplastics (250 nanometers) were small enough to pass through the protective egg membrane and directly reach the embryo. The nanoplastics caused heart rate changes and neurotoxic effects at the larval stage, while the larger microplastics mainly affected the embryos indirectly from outside. This demonstrates that smaller plastic particles are more dangerous during early development because they can bypass protective barriers.
Effects of nanoplastics on zebrafish embryo-larval stages: A case study with polystyrene (PS) and polymethylmethacrylate (PMMA) particles
Researchers assessed the effects of polystyrene and polymethylmethacrylate nanoparticles on zebrafish embryos and larvae over 96 hours. The study found that these nanoplastics affected biochemical endpoints related to neurotransmission, antioxidant status, oxidative damage, and energy metabolism, with effects varying by plastic type. Evidence suggests that smaller plastic particles may have increased bioavailability and reactivity compared to larger fragments.
[Effects of Microplastics on Embryo Hatching and Intestinal Accumulation in Larval Zebrafish Danio rerio].
Researchers examined the effects of two sizes of polystyrene microplastics (10 µm and 0.5 µm) on embryo hatching rates and intestinal accumulation in fish larvae, finding that the smaller submicron particles accumulated more readily in intestinal tissue, raising concerns about early developmental exposure.
DistinctEffects between Polystyrene Micro- and Nanoplastics:Exacerbation of Adverse Outcomes in Inflammatory Bowel Disease-likeZebrafish and Mice
Researchers compared the effects of polystyrene micro- and nanoplastics on a biological system, finding that nanoplastics caused more severe adverse effects than microplastics at equivalent mass doses, likely due to greater surface area and cellular penetration capacity.
Polystyrene Nanoplastic Exposure Induces Developmental Toxicity by Activating the Oxidative Stress Response and Base Excision Repair Pathway in Zebrafish (Danio rerio)
Researchers exposed zebrafish embryos to polystyrene nanoplastics at various concentrations and found significant developmental abnormalities including reduced hatching rates and increased malformations. The nanoplastics activated oxidative stress responses and DNA repair pathways, indicating cellular damage during critical early development stages. The study provides mechanistic evidence for how nanoplastic exposure can disrupt normal embryonic development in aquatic organisms.
Embryotoxicity of polystyrene microplastics in zebrafish Danio rerio
Researchers exposed zebrafish embryos to polystyrene microplastics during early development and observed serious physical deformities, particularly in the spine, tail, and eyes, despite no increase in mortality. The exposed larvae also showed elevated expression of genes involved in oxidative stress defense and cellular detoxification. The findings suggest that microplastics can disrupt critical developmental stages in freshwater fish even when they do not directly cause death.
Distinctive lipidomic responses induced by polystyrene micro- and nano-plastics in zebrafish liver cells
Researchers compared how micro-sized and nano-sized polystyrene plastic particles affect fat metabolism in zebrafish liver cells. They found that both sizes were taken up by cells, but the smaller nanoplastics caused more pronounced disruptions to lipid profiles and triggered cell death pathways. The findings underscore that particle size matters when assessing the biological impact of plastic pollution on fish.
Molecular effects of polystyrene nanoplastics toxicity in zebrafish embryos (Danio rerio)
Researchers exposed zebrafish embryos to polystyrene nanoplastics at various concentrations and measured gene expression changes related to stress, inflammation, and DNA repair. They found dose-dependent activation of oxidative stress and apoptotic pathways at the highest concentration, along with inhibition of the neurotransmitter-related gene acetylcholinesterase and DNA repair genes. The study suggests that nanoplastic exposure at the molecular level may compromise cellular defense mechanisms and neurological function in developing fish.
Toxicity of nanoplastics for zebrafish embryos, what we know and where to go next
This review integrates findings from studies on how polystyrene nanoplastics affect zebrafish embryo development, a widely used model for understanding toxicity. Researchers found that the functional coating on nanoplastic surfaces had a greater influence on toxic effects than particle size or concentration alone. The study highlights that surface chemistry is a critical and often overlooked factor in nanoplastic toxicity, and calls for more standardized study designs to improve comparability across research.