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61,005 resultsShowing papers similar to Effects of environmentally relevant mixtures of microplastics on terrestrial organisms
ClearEffects 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.
Effects of environmentally relevant mixtures of microplastics on soil organisms
Researchers exposed earthworms and springtails to environmentally realistic mixtures of microplastics commonly found in agricultural soils treated with sewage sludge. They found that earthworms ingested microplastics in proportion to exposure levels, and at higher concentrations, both species showed reduced reproduction. The study provides evidence that real-world microplastic mixtures in farm soils can affect important soil organisms at concentrations already found in the environment.
What do we know about how the terrestrial multicellular soil fauna reacts to microplastic?
This review analyzed the available literature on how soil-dwelling animals respond to microplastics and found evidence of uptake, bioaccumulation, and harmful effects across many groups including earthworms, springtails, and beetles. Most studies used high concentrations not yet found in real soils, limiting conclusions about current environmental risks.
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.
Comparison of fitness effects in the earthworm Eisenia fetida after exposure to single or multiple anthropogenic pollutants
Researchers compared single and combined pollutant exposures on the earthworm Eisenia fetida, finding that mixtures of pesticides, heavy metals, particulate matter, and microplastics can produce synergistic negative effects on survival and reproduction beyond individual pollutant impacts.
Combined effects of polyethylene microplastics and carbendazim on Eisenia fetida: A comprehensive ecotoxicological study
Researchers studied the combined effects of polyethylene microplastics and the pesticide carbendazim on earthworms and found that the two pollutants together caused worse damage than either alone. The combined exposure led to growth problems, oxidative stress, and organ damage even at lower concentrations. Since earthworms are essential for soil health and microplastics and pesticides commonly co-exist in farmland, these findings suggest that agricultural soil contamination could have cascading effects on the food system.
Microplastics as Soil Emerging Pollutants: Sublethal Earthworms Answers From Poly(propene) Photodegraded
Researchers exposed the earthworm Eisenia andrei to polypropylene microplastics at various concentrations in soil for 14 days, finding sublethal effects on survival, reproduction, and oxidative stress markers that varied with MP concentration and confirmed ecotoxicological risk to soil invertebrates.
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.
Combined toxicity of polyethylene microplastics and nickel oxide nanoparticle on earthworm (Eisenia andrei): oxidative stress responses, bioavailability and joint effect
Researchers studied the combined toxicity of polyethylene microplastics and nickel oxide nanoparticles on earthworms over 28 days. They found that smaller microplastics caused greater oxidative stress, and the combination of both pollutants was more harmful than either one alone. The study suggests that the co-occurrence of microplastics and metal nanoparticles in soil can amplify negative effects on soil-dwelling organisms.
Distinct responses of Caenorhabditis elegans to polyethylene microplastics and plant secondary metabolites
Researchers studied how polyethylene microplastics and plant-derived chemical compounds individually and together affect the roundworm C. elegans, a common soil organism. They found that while the plant compounds reduced worm reproduction and lifespan, microplastics had milder individual effects but modified the toxicity of the plant chemicals when combined. The study reveals that in real soil environments, the interactions between microplastics and natural plant chemicals create complex toxicity patterns.
What do we know about how the terrestrial multicellular soil fauna reacts to microplastic?
This review analyzed published studies on how multicellular soil organisms (including earthworms, mites, springtails, and nematodes) ingest and respond to microplastics, finding that most studies used unrealistically high concentrations and that ecologically relevant effects on soil fauna remain poorly characterized.
Microplastic-Earthworm Interactions: A Critical Review
This critical review examines how microplastics from diverse plastic waste categories accumulate in terrestrial and aquatic ecosystems and interact with earthworms, a key soil organism. The authors synthesize evidence on the deleterious effects of increasing microplastic concentrations on soil properties, microbiota, and earthworm physiology.
Metabolomics insights into the combined effects of boscalid and polystyrene microplastics on earthworms (Eisenia fetida): The critical role of pesticide dose and microplastics size
Researchers studied the combined effects of the pesticide boscalid and polystyrene microplastics on earthworms, finding that the interaction between the two contaminants significantly altered earthworm metabolic profiles. The severity of effects depended on both the pesticide dose and the size of the microplastic particles. The study highlights that microplastics in agricultural soils may interact with pesticides to create synergistic toxic effects on soil organisms.
First approach to assess the effects of nanoplastics on the soil species Folsomia candida: A mixture design with bisphenol A and diphenhydramine
Researchers examined how nanoplastics interact with bisphenol A and diphenhydramine in soil, finding that nanoplastics can modulate the toxicity of co-contaminants to the springtail Folsomia candida, acting as carriers that alter chemical bioavailability.
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.
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.
Combined ecotoxicological effects of different-sized polyethylene microplastics and imidacloprid on the earthworms (Eisenia fetida)
Researchers exposed earthworms to different sizes of polyethylene microplastics combined with the pesticide imidacloprid and found that particle size significantly influenced the combined toxic effects. Smaller microplastics tended to increase pesticide toxicity more than larger ones, affecting earthworm survival, growth, and antioxidant responses. The findings highlight how microplastic size matters when assessing the joint environmental risks of plastic pollution and agricultural chemicals in soil.
Interaction of Invertebrates and Synthetic Polymers in Soil: A Review
This review summarizes how microplastics in soil harm invertebrates including nematodes, springtails, and earthworms, while some soil animals can fragment or ingest and transport plastic particles. The presence of microplastics in soil disrupts the gut function of soil organisms that play critical roles in maintaining healthy, productive soils.
Implication of microplastics on soil faunal communities — identifying gaps of knowledge
This systematic review examines how microplastics in soil affect earthworms, springtails, mites, and other soil-dwelling creatures that are essential for healthy soil. The impacts are highly variable and depend on the type of plastic, particle size, and soil conditions, making broad conclusions difficult. The review identifies critical knowledge gaps, noting that most studies use unrealistically high microplastic concentrations, and calls for research at levels that match actual field conditions.
Plastic pollution in terrestrial ecosystems: Current knowledge on impacts of micro and nano fragments on invertebrates
This review summarizes research on how micro- and nanoplastics affect soil-dwelling invertebrates like earthworms and insects, finding that effects vary widely depending on plastic type, shape, concentration, and exposure time. While no broad conclusions could be drawn, the documented sublethal effects on soil organisms could disrupt the soil ecosystems that support the crops humans depend on for food.
Ecotoxicological risk of co-exposure to fosthiazate and microplastics on earthworms (Eisenia fetida): Integrating biochemical and transcriptomic analyses
Researchers investigated the combined toxic effects of the insecticide fosthiazate and microplastics on earthworms using both biochemical and genetic analyses. They found that co-exposure increased oxidative stress, DNA damage, and disrupted metabolic pathways more severely than either pollutant alone. The study suggests that microplastics may amplify pesticide toxicity in soil organisms, raising concerns about their combined impact on soil ecosystem health.
Reproduction, metabolic enzyme activity, and metabolomics in earthworms Eisenia fetida exposed to different polymer microplastics
Researchers exposed earthworms to microplastics from three different polymer types, including both conventional and biodegradable plastics, at environmentally relevant concentrations. They found that polypropylene microplastics had the most pronounced effects on reproduction and metabolic enzyme activity, while biodegradable plastics also disrupted earthworm metabolism. The study demonstrates that different plastic polymers pose varying levels of risk to soil-dwelling organisms.
A comparison of the toxicity induced by the exposure to microplastics made of a conventional and a biodegradable polymer on the earthworm Eisenia fetida
Researchers compared the toxicity of conventional versus biodegradable polymer microplastics on the earthworm Eisenia fetida, evaluating whether biodegradable alternatives present reduced ecotoxicological risk in soil environments where microplastic contamination is increasingly documented.
Co-Exposure of Nanopolystyrene and Other Environmental Contaminants—Their Toxic Effects on the Survival and Reproduction of Enchytraeus crypticus
This study tested the combined toxicity of nanopolystyrene particles alongside pharmaceuticals, metals, and engineered nanomaterials on the soil worm Enchytraeus crypticus, finding that co-exposure often amplified harm to survival and reproduction beyond that of each pollutant alone. The results highlight that real-world mixtures of plastic and chemical contaminants pose greater ecological risks than single-substance assessments suggest.