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61,005 resultsShowing papers similar to Uptake of Potentially Toxic Elements in Microplastic-Contaminated Soils: A Controlled Laboratory Study Using Eisenia Fetida
ClearCadmium and copper absorption by Eisenia fetida in the presence of different concentrations of microplastics
Researchers exposed earthworms (Eisenia fetida) to soil containing tire-derived microplastics alongside heavy metals cadmium and copper, finding that the microplastics increased the worms' uptake of both toxic metals. The results suggest that microplastics in soil act as carriers that make heavy metal contamination more bioavailable and dangerous for soil-dwelling organisms.
Effect of Microplastics on the Bioavailability of (Semi-)Metals in the Soil Earthworm Eisenia fetida
Researchers studied how polystyrene microplastics affect the uptake of cadmium and arsenic by earthworms in paddy soil. They found that microplastics altered the soil chemistry in ways that changed how much of these metals the earthworms absorbed, with effects varying by metal type and concentration. The study suggests that microplastics in contaminated agricultural soils can influence how toxic metals move through the food chain.
Ecotoxicological effects of micronized car tire wear particles and their heavy metals on the earthworm (Eisenia fetida) in soil
Researchers exposed earthworms to microplastics from ground-up car tires at various concentrations and sizes over 14 and 28 days. They found that the worms preferentially consumed smaller particles, which led to increased heavy metal accumulation and significant signs of oxidative stress at higher concentrations. The study highlights that tire-derived microplastics in soil can harm terrestrial organisms through both physical ingestion and the release of associated toxic metals.
Impacts of polyethylene microplastics on bioavailability and toxicity of metals in soil
Researchers studied how polyethylene microplastics affect the bioavailability and toxicity of copper and nickel in soil using earthworms as test organisms. They found that adding microplastics to contaminated soil increased the bioavailability of the metals and enhanced their toxic effects on the earthworms. The study suggests that microplastics in soil can worsen heavy metal pollution by making metals more accessible and harmful to soil-dwelling organisms.
Microplastics impact the accumulation of metals in earthworms by changing the gut bacterial communities
Researchers exposed earthworms to three sizes of polystyrene microplastics (0.1, 10, and 100 micrometers) to study effects on metal accumulation and gut bacteria. The study found that microplastics reduced nickel and lead accumulation in earthworms while significantly altering gut bacterial communities. The results suggest that microplastics influence heavy metal bioavailability in soil organisms by changing gut microbiome composition.
Impacts of microplastics and heavy metals on the earthworm Eisenia fetida and on soil organic carbon, nitrogen, and phosphorus
Researchers found that co-contamination by polypropylene microplastics and heavy metals (Cu, Cr, Zn) had synergistic adverse effects on earthworms and soil quality, reducing organic carbon and nitrogen levels more than either contaminant alone.
Plastic Bag Derived-Microplastics as a Vector for Metal Exposure in Terrestrial Invertebrates
Researchers investigated whether microplastics from degraded plastic bags could serve as carriers of zinc contamination to earthworms in soil. Laboratory tests showed that zinc desorbed more readily from microplastics than from soil under conditions mimicking an earthworm's gut, suggesting increased bioavailability. However, in live earthworm experiments, no significant zinc accumulation or harm was observed, indicating that for well-regulated essential metals the actual ecological risk may be limited.
Ecotoxicological effects of microplastics and cadmium on the earthworm Eisenia foetida
Researchers studied the effects of microplastics alone and combined with the heavy metal cadmium on earthworms over 42 days. They found that both exposures reduced growth and increased mortality, with the combined treatment causing the most damage through increased oxidative stress. The study also revealed that microplastics can increase cadmium accumulation in earthworms by up to 161%, suggesting microplastics may worsen heavy metal contamination in soil ecosystems.
Earthworms on a microplastics diet
Researchers found that environmentally relevant concentrations of polyethylene microplastics added to plant litter on soil surfaces led to reduced growth and elevated mortality in the earthworm Lumbricus terrestris, and that earthworms may themselves transport ingested microplastics deeper into soils.
Environmentally relevant concentrations of microplastics from agricultural mulch and cadmium negatively impact earthworms by triggering neurotoxicity and disrupting homeostasis
Researchers exposed earthworms to environmentally realistic levels of microplastics from agricultural mulch film combined with cadmium, a toxic heavy metal. The aged microplastics helped carry more cadmium into the earthworms' bodies, causing nerve damage, gut tissue injury, and disrupted metabolism. This study shows that microplastics in farm soil can make heavy metal contamination worse for soil organisms, with potential knock-on effects for the food chain.
Impacts of microplastics and heavy metals on the earthworm Eisenia foetida and on soil organic carbon, nitrogen and phosphorus
Researchers assessed the combined effects of polypropylene microplastics and a heavy metal mixture (copper, chromium, and zinc) on the earthworm Eisenia foetida and on soil organic carbon, nitrogen, and phosphorus cycling. The study found that co-contamination exacerbated adverse effects on earthworm survival and soil nutrient dynamics compared to single-pollutant exposures, highlighting synergistic risks of combined microplastic and metal pollution in terrestrial ecosystems.
Microplastics aggravate the joint toxicity to earthworm Eisenia fetida with cadmium by altering its availability
Researchers exposed earthworms to polyethylene microplastics combined with cadmium and found that co-exposure caused significantly worse effects than either pollutant alone, including increased avoidance behavior, weight loss, and DNA damage. The microplastics increased the bioavailability of cadmium in soil by up to 1.43-fold and boosted cadmium accumulation in earthworm tissue by up to 2.65-fold. The study demonstrates that microplastics can worsen heavy metal toxicity to soil organisms by making the metals more accessible for uptake.
Influence of aged and pristine polyethylene microplastics on bioavailability of three heavy metals in soil: Toxic effects to earthworms (Eisenia fetida)
Researchers studied how aging affects the ability of polyethylene microplastics to influence the bioavailability of zinc, lead, and cadmium in soil, and the resulting toxicity to earthworms. The study found that aged microplastics had different adsorption properties for heavy metals compared to pristine particles, which altered the bioavailability of these metals and affected earthworm health differently depending on microplastic concentration and aging status.
Insight into Bioaccumulation of Decabromodiphenyl Ethane in Eisenia fetida Increased by Microplastics
Researchers found that microplastics made from electronics casings significantly increased the accumulation of a brominated flame retardant chemical in earthworms over time. While the microplastics initially slowed absorption of the chemical, after 28 days they promoted greater bioaccumulation by altering the soil environment and the earthworms' gut bacteria. The study suggests that the co-occurrence of electronic waste microplastics and flame retardants in soil may amplify chemical exposure in soil organisms.
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.
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.
A Systematic Review of Nano- and Microplastic (NMP) Influence on the Bioaccumulation of Environmental Contaminants: Part I—Soil Organisms
This systematic review investigates whether microplastics and nanoplastics help other environmental contaminants like heavy metals and pesticides accumulate in soil organisms. The research finds that the presence of plastic particles can change how much of these pollutants earthworms and other soil creatures absorb. This matters because contaminants that build up in soil organisms can eventually work their way into the food we grow and eat.
Accumulation of HOCs via Precontaminated Microplastics by Earthworm Eisenia fetida in Soil
Researchers incubated earthworms in soil amended with five types of microplastics precontaminated with polychlorinated biphenyls and polycyclic aromatic hydrocarbons to assess whether pre-contaminated MPs enhance HOC transfer to terrestrial organisms. Results showed that precontaminated microplastics significantly increased earthworm accumulation of PCBs and PAHs compared to controls, demonstrating that the contamination history of MPs entering soil is a critical but overlooked factor in risk assessment.
Microplastics and earthworms in soils: A case study on translocation, toxicity and fate
This conference abstract presents research on how earthworms in agricultural soils interact with microplastics, examining whether worms translocate particles deeper into soil, experience toxic effects, and alter the fate of microplastic contamination. Earthworms are key soil engineers, and their exposure to microplastics could have cascading effects on soil health.
Combined toxicity of organophosphate flame retardants and polyethylene microplastics on Eisenia fetida: Biochemical and molecular insights
Researchers exposed earthworms to polyethylene microplastics, chlorinated flame retardants, and their combinations to assess combined toxicity effects. They found that the most toxic flame retardant (TDCPP) had its effects reduced when combined with microplastics, likely because the plastics absorbed the chemical and lowered its bioavailability. In contrast, microplastics enhanced the toxicity of another flame retardant (TCPP), demonstrating that microplastics can act as both carriers and modulators of co-contaminant toxicity in soil ecosystems.
Effects of environmentally relevant mixtures of microplastics on terrestrial organisms
Researchers tested the effects of environmentally realistic microplastic mixtures on the earthworm Eisenia andrei and the springtail Folsomia candida as soil model organisms. Even at environmentally relevant concentrations, the microplastic mixture caused measurable negative effects on soil organism health and reproduction.
The Effect of Microplastic on the Uptake of Chemicals by the Lugworm Arenicola marina (L.) under Environmentally Relevant Exposure Conditions
Researchers used the lugworm Arenicola marina to test whether microplastics affect the uptake of co-occurring chemicals, finding that microplastics altered the bioavailability of chemicals and modified their uptake and distribution in worm tissues.
Microplastics in Mediterranean Agricultural Soils: Effects on Soil Properties, Metal Accumulation in Plants, and Implications for Sustainable Agroecosystems
Scientists found that tiny plastic particles in soil make it easier for toxic metals like lead and zinc to move into plants we might eat. Even small amounts of microplastics changed how metals behave in the soil, with some types of plastic causing up to 20% more metal absorption in plants. This matters because these contaminated plants could end up in our food supply, potentially increasing our exposure to harmful metals.
Negligible effects of microplastics on animal fitness and HOC bioaccumulation in earthworm Eisenia fetida in soil
Researchers exposed earthworms to polyethylene and polystyrene microplastics at concentrations up to 20 percent of soil dry weight and measured oxidative stress biomarkers. While the highest concentration caused some biochemical changes, no significant effects were observed at 10 percent or below, which covers most realistic environmental scenarios. The study also found that microplastics reduced the bioaccumulation of PAHs and PCBs in earthworm tissues, suggesting that the particles may actually limit the uptake of certain organic pollutants in soil organisms.