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61,005 resultsShowing papers similar to Nanoplastics induces oxidative stress and triggers lysosome-associated immune-defensive cell death in the earthworm Eisenia fetida
ClearPolystyrene Nanoplastics Elicit Multiple Responses in Immune Cells of the Eisenia fetida (Savigny, 1826)
This study examined how nanoplastics from polystyrene affect the immune cells of earthworms, which play a critical role in soil ecosystems. Researchers found that the tiny plastic particles were taken up by the cells, triggered oxidative stress, weakened antioxidant defenses, destabilized cell membranes, and initiated early-stage cell death. The results provide cellular-level evidence that nanoplastic exposure poses ecological risks to soil-dwelling organisms.
Molecular mechanisms of nano-sized polystyrene plastics induced cytotoxicity and immunotoxicity in Eisenia fetida
Researchers studied how polystyrene nanoplastics affect earthworm immune cells and found that exposure caused significant oxidative stress, DNA damage, and weakened immune function. The nanoplastics physically bound to and damaged lysozyme, a key immune protein, impairing the earthworms' ability to fight off infections. Since earthworms are essential soil organisms, this immune damage could have cascading effects on soil health and the agricultural systems that humans depend on.
Nanoplastics induce molecular toxicity in earthworm: Integrated multi-omics, morphological, and intestinal microorganism analyses
Researchers used multi-omics analysis to study how even low concentrations of nanoplastics affect earthworms, important indicators of soil health. They found that nanoplastics accumulated in the earthworms' intestines, damaging their digestive and immune systems and disrupting gut microorganism communities. The study demonstrates that nanoplastics can cause molecular-level harm to soil organisms at concentrations that might be considered environmentally realistic.
The toxic differentiation of micro- and nanoplastics verified by gene-edited fluorescent Caenorhabditis elegans
Researchers used gene-edited fluorescent C. elegans to demonstrate that nanoplastic toxicity is size- and charge-dependent, with 100 nm positively charged polystyrene particles causing the greatest harm through intestinal accumulation and oxidative stress.
Toxicological effects of polystyrene microplastics on earthworm (Eisenia fetida)
Researchers exposed earthworms to two sizes of polystyrene microplastics in soil for 14 days and found evidence of intestinal cell damage, oxidative stress, and DNA damage. The larger particles accumulated more in earthworm intestines, while both sizes triggered changes in key antioxidant markers. The study demonstrates that microplastic contamination in soil can cause measurable biological harm to important soil organisms.
Ecotoxicological effects of different size ranges of industrial-grade polyethylene and polypropylene microplastics on earthworms Eisenia fetida
Researchers exposed earthworms to industrial-grade polyethylene and polypropylene microplastics of various sizes and found that the worms ingested all types of particles tested. The microplastics caused oxidative stress and DNA damage in the earthworms, with the severity depending on both the size and type of plastic. Gene analysis revealed that exposure disrupted pathways related to nervous system function, oxidative stress, and inflammation, indicating that microplastics pose ecological risks to important soil organisms.
Multigenerational growth inhibition and oxidative stress of polystyrene micro(nano)plastics on earthworms (Eisenia fetida)
Researchers exposed earthworms to polystyrene nano- and microplastics across two generations, finding both particle types reduced offspring numbers by 23–39%, disrupted reproductive tissue structure, and caused oxidative stress, with nanoplastics producing more severe multigenerational effects.
New regulatory mechanisms of polystyrene nanoplastics on the ecological risk of zinc: Cellular oxidative injury and molecular toxicity mechanisms in soil sentinel organisms (Eisenia fetida)
Researchers investigated how nanoplastics and zinc interact to affect earthworm cells and a key antioxidant defense enzyme. While nanoplastics alone had minimal effect, combining them with zinc dramatically increased cell death beyond what zinc caused on its own, and molecular modeling showed nanoplastics can physically bind to and potentially block the antioxidant enzyme. The findings suggest that nanoplastics may worsen the toxicity of heavy metals in soil by interfering with organisms' natural defense mechanisms.
The combined effects of polystyrene nanoplastics with nickel on oxidative stress and related toxic effects to earthworms from individual and cellular perspectives
Researchers studied the combined toxic effects of polystyrene nanoplastics and nickel on earthworms at both the individual and cellular levels. They found that nanoplastics amplified the harmful effects of nickel by increasing oxidative stress, reducing cell viability, and disrupting the balance between protective and damaging molecules in cells. The findings suggest that nanoplastics can worsen the toxicity of heavy metals already present in contaminated soils.
Size effects of polystyrene microplastics on the accumulation and toxicity of (semi-)metals in earthworms
Researchers studied how different sizes of polystyrene microplastics and nanoplastics affect the uptake of cadmium and arsenic in earthworms. They found that microplastics facilitated greater accumulation of these metals than nanoplastics by damaging intestinal integrity, with proteomic and metabolomic analysis revealing disruptions to the earthworms' immune and metabolic systems.
Understanding the harmful effects of polyethylene microplastics on Eisenia fetida: A toxicological evaluation
Earthworms (Eisenia fetida) exposed to increasing concentrations of polyethylene microplastics in soil showed lower body weight, reduced reproductive output, and disrupted antioxidant defenses — with oxidative stress markers climbing nearly 1.3-fold at the highest dose. These findings confirm that microplastic pollution degrades soil ecosystem health at concentrations that could plausibly occur in contaminated agricultural land.
Randomly-shaped nanoplastics induced stronger biotoxicity targeted to earthworm Eisenia fetida species: Differential effects and the underlying mechanisms of realistic and commercial polystyrene nanoplastics
Researchers compared the toxicity of commercially produced spherical nanoplastics with irregularly shaped nanoplastics that more closely resemble what is found in the real environment, testing both on earthworms. The randomly shaped particles were significantly more toxic, causing greater oxidative stress, DNA damage, and tissue injury at lower concentrations. The findings suggest that most lab studies using uniform spherical particles may underestimate the actual environmental risks of nanoplastic pollution.
Redefining the synergistic toxicity of nano-plastics and cadmium in earthworm coelomocytes: the mechanism of α-amylase molecular docking orientation and energy crisis
Researchers exposed earthworm immune cells (coelomocytes) to polystyrene nanoplastics combined with the heavy metal cadmium, finding that nanoplastics act as carriers that amplify cadmium uptake and worsen oxidative stress, energy metabolism disruption, and enzyme damage beyond what cadmium causes alone.
Environmental relevant concentrations of polystyrene nanoplastics and lead co-exposure triggered cellular cytotoxicity responses and underlying mechanisms in Eisenia fetida
Researchers studied how polystyrene nanoplastics and lead, a toxic heavy metal, interact when earthworm immune cells are exposed to both simultaneously at environmentally realistic concentrations. The combined exposure caused more severe cell damage, oxidative stress, and inflammation than either pollutant alone. The findings suggest that nanoplastics can increase the harmful effects of heavy metals on soil organisms, raising concerns about the real-world impact of mixed contaminant exposure.
In vitro cultivation of primary intestinal cells from Eisenia fetida as basis for ecotoxicological studies
Researchers isolated living intestinal cells from earthworms to test how pollutants affect them at the cellular level, finding that silver nanoparticles and heavy metals reduced cell metabolism while microplastic particles (polystyrene and PLA beads) showed only minor effects and were not actively absorbed by the cells.
Effects of polyethylene microplastics stress on soil physicochemical properties mediated by earthworm Eisenia fetida
Researchers exposed earthworms to polyethylene microplastics of two sizes and found that smaller particles (13 micrometers) were more toxic than larger ones (130 micrometers), reducing survival and growth more severely. The microplastics caused oxidative stress in the worms and altered key soil properties including pH and organic carbon content. Since earthworms play a vital role in maintaining healthy soil for agriculture, this damage could affect soil quality and ultimately the food grown in microplastic-contaminated farmland.
Microplastic pollution inhibits the phagocytosis of E. coli by earthworm immune cells in soil
Researchers discovered that polystyrene microplastics inhibit the ability of earthworm immune cells to engulf bacteria through phagocytosis, both in laboratory tests and in soil experiments. The microplastics also caused mitochondrial damage in intestinal tissue and suppressed oxidative stress responses in immune cells. This is the first study to demonstrate that microplastic pollution in soil can compromise the immune defenses of earthworms, key organisms in soil ecosystem health.
Visualizing and assessing the size-dependent oral uptake, tissue distribution, and detrimental effect of polystyrene microplastics in Eisenia fetida
Researchers investigated size-dependent effects of polystyrene microplastics on earthworms (Eisenia fetida) using particles of 70 nanometers, 1 micrometer, and 10 micrometers at various doses. They found that smaller particles were more readily taken up into tissues and caused greater oxidative stress and tissue damage. The study suggests that nanoscale plastic particles may pose higher ecological risks to soil organisms than larger microplastics due to their enhanced ability to penetrate biological barriers.
Defense responses in earthworms (Eisenia fetida) exposed to low-density polyethylene microplastics in soils
Researchers exposed earthworms to low-density polyethylene microplastics in soil at various concentrations for 28 days. They found that the earthworms ingested microplastics in a dose-dependent manner and actually broke some particles into smaller pieces during digestion, with about 30% more particles under 100 micrometers found in their excrement compared to the original soil. At higher concentrations, the microplastics triggered oxidative stress and neurotoxic responses, suggesting potential ecological risks to soil organisms.
Potential toxicity of nanopolystyrene on lifespan and aging process of nematode Caenorhabditis elegans
Researchers chronically exposed C. elegans to nanopolystyrene across their aging lifespan and found that high concentrations shortened lifespan while lower concentrations still impaired locomotion and elevated intestinal reactive oxygen species in older animals, with nanoplastic exposure progressively suppressing immune genes, antioxidant defenses, and mitochondrial stress responses as worms aged.
Evaluation of nanoplastics toxicity in the soil nematode Caenorhabditis elegans by iTRAQ-based quantitative proteomics
Researchers used quantitative proteomics to evaluate nanoplastic toxicity in the nematode C. elegans, identifying disrupted proteins involved in oxidative stress, metabolism, and cellular defense pathways, providing molecular-level insight into how nanoplastics harm organisms.
Effect of polyethylene microplastics on tebuconazole bioaccumulation, oxidative stress, and intestinal bacterial community in earthworms
Researchers exposed earthworms to polyethylene microplastics of different sizes alongside a common fungicide and found that smaller microplastics caused the most severe oxidative stress and DNA damage. The microplastics also changed how much fungicide accumulated in the earthworms and disrupted their gut bacteria. This matters because earthworms are essential for soil health, and these effects could ripple through agricultural ecosystems that produce our food.
Fecal microbiota transplantation attenuates nano-plastics induced toxicity in Caenorhabditis elegans.
Nano-sized plastic particles ingested by the roundworm C. elegans penetrated the intestinal barrier, accumulated throughout the body, and were not excreted until the worms died — and transplanting human gut microbiota into the worms partially mitigated the toxicity. The study provides early evidence that a healthy gut microbiome may help protect against nanoplastic harm, and that these particles can persist indefinitely once inside an organism.
Combined Effects of Micro- and Nanoplastics at the Predicted Environmental Concentration on Functional State of Intestinal Barrier in Caenorhabditis elegans
Researchers used the roundworm C. elegans to study the combined effects of nano- and micro-sized polystyrene particles at concentrations similar to what is found in the environment. They found that co-exposure caused more severe intestinal damage than either particle size alone, including increased oxidative stress and impaired gut barrier function. The study suggests that the real-world mixture of different-sized plastic particles may be more harmful than studies of single sizes would predict.