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20 resultsShowing papers similar to Evaluation of the impact of polylactide microparticles on soil biota
ClearShort-Term Effect of Poly Lactic Acid Microplastics Uptake by Earthworms, Eudrilus eugeniae.
Researchers tested whether earthworms (Eudrilus eugeniae) would ingest polylactic acid (PLA) biodegradable microplastics when mixed with organic matter, finding they did but with reduced weight gain and reproductive output at higher concentrations. This suggests even biodegradable microplastics can harm soil organisms, which are essential for nutrient cycling and soil health.
The comparison effect on earthworms between conventional and biodegradable microplastics
Researchers compared the effects of conventional polyethylene and biodegradable polylactic acid microplastics on earthworms over an extended exposure period. They found that biodegradable microplastics caused comparable or even greater harm than conventional plastics at certain concentrations, including reduced growth and reproduction. The findings challenge the assumption that biodegradable plastics are inherently safer for soil organisms.
Short- and medium-term effects of biodegradable microplastics (PLA and PHB) on earthworm development and reproduction
Researchers tested whether biodegradable plastics (PLA and PHB) are truly safer for soil organisms than conventional polyethylene by exposing earthworms to all three types of microplastics. While none caused immediate harm or death, both PLA and conventional polyethylene reduced earthworm reproduction over medium-term exposure, producing fewer cocoons and offspring. This challenges the assumption that biodegradable plastics are environmentally harmless and suggests they may pose similar risks to soil ecosystems as conventional plastics.
Biodegradable polymers boost reproduction in the earthworm Eisenia fetida
This study compared how conventional plastics and biodegradable polymers affect earthworms in soil. Surprisingly, biodegradable plastics like PLA and PBAT boosted earthworm reproduction, likely because soil microbes can partially break them down into usable carbon sources. However, conventional plastics like polystyrene and PET had neutral to negative effects, highlighting that not all microplastics impact soil organisms the same way.
Responses of earthworms exposed to low-density polyethylene microplastic fragments
Researchers exposed earthworms to low-density polyethylene microplastic fragments at various concentrations and studied the effects on their survival, growth, and reproduction. The microplastics affected earthworm behavior and caused measurable changes depending on concentration and exposure time. Since earthworms are critical for soil health and nutrient cycling, their sensitivity to microplastics raises concerns about how plastic pollution may degrade agricultural soils.
Effects of polystyrene microplastics on the fitness of earthworms in an agricultural soil
Researchers exposed earthworms to polystyrene microplastics in agricultural soil at various concentrations. The study found that low concentrations had little effect, but high concentrations (1% and above) significantly inhibited growth and increased mortality, suggesting microplastic pollution poses ecological risks to soil organisms in terrestrial ecosystems.
Effect of conventional and biodegradable microplastics on earthworms during vermicomposting process
Researchers compared the effects of conventional polyethylene and biodegradable microplastics on earthworms during composting and found that both types caused stress at higher concentrations. Earthworm weight, reproduction, and survival were negatively affected by both plastic types, though biodegradable microplastics caused somewhat less harm. The findings suggest that biodegradable plastics are not entirely safe for soil organisms and can still disrupt composting processes.
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.
Assessment of the Effect of PHBV-Based Bioplastic Microparticles on Soil Organisms
Researchers tested the effects of PHBV bioplastic microparticles on soil organisms using plants and earthworms in a small terrestrial model ecosystem. They found that PHBV microparticles did not affect plant germination or earthworm survival, but reduced plant dry matter and caused earthworms to move deeper into the soil, suggesting avoidance behavior. The study also identified chemical compounds released from PHBV leachates, indicating that even bioplastics warrant environmental safety evaluation.
Microplastics Effects on Reproduction and Body Length of the Soil-Dwelling Nematode Caenorhabditis elegans
Researchers compared the effects of conventional low-density polyethylene microplastics and biodegradable polymer microplastics on reproduction and body length in the soil nematode C. elegans. The study found that microplastic exposure affected these organisms, highlighting that even biodegradable plastics may pose risks to soil-dwelling invertebrates and that terrestrial microplastic toxicity deserves greater research attention.
Comparison of the potential toxicity induced by microplastics made of polyethylene terephthalate (PET) and polylactic acid (PLA) on the earthworm Eisenia foetida
Researchers compared the toxicity of microplastics made from conventional PET plastic and biodegradable PLA plastic on earthworms. Surprisingly, the supposedly eco-friendly PLA particles caused more harm than PET, triggering oxidative stress, tissue damage, and behavioral changes in the worms. This challenges the assumption that bioplastics are always safer for soil organisms than traditional plastics.
Impacts of conventional and biodegradable microplastics on the earthworm Eisenia andrei
Researchers compared the ecotoxicological effects of conventional low-density polyethylene microplastics and biodegradable polybutylene adipate terephthalate microplastics on the earthworm Eisenia andrei using an eight-week reproduction test across seven concentration levels. Both polymer types affected earthworm survival, reproduction, and oxidative stress markers, raising questions about whether biodegradable alternatives pose similar soil ecosystem risks.
Dose Effect of Polyethylene Microplastics Derived from Commercial Resins on Soil Properties, Bacterial Communities, and Enzymatic Activity
Researchers applied polyethylene microplastics derived from commercial resins to soil at varying doses and measured effects on soil organisms and properties, finding dose-dependent impacts on earthworm behavior, enzyme activity, and nutrient cycling.
Impacts of conventional and biodegradable microplastics on the earthworm Eisenia andrei
Researchers compared the ecotoxicological effects of conventional low-density polyethylene microplastics (PE-MPs) and biodegradable polybutylene adipate terephthalate microplastics (PBAT-BD-MPs) on earthworms (Eisenia andrei) across a range of concentrations in an eight-week reproduction test. Both polymer types were assessed for impacts on survival, reproduction, growth, and oxidative stress in soil organisms.
Reassessing Whether Biodegradable Microplastics Are Environmentally Friendly: Differences in Earthworm Physiological Responses and Soil Carbon Function Impacts
Researchers compared the toxic effects of conventional (PP, PS) and biodegradable (PLA, PHA) microplastics on earthworm physiology and soil carbon function in haplic phaeozem soil. Biodegradable MPs were not environmentally friendly — PLA and PHA caused comparable or greater physiological stress in earthworms and disrupted soil carbon cycling to a similar degree as conventional plastics.
Effects of conventional versus biodegradable microplastic exposure on oxidative stress and gut microorganisms in earthworms: A comparison with two different soils
Researchers compared the toxic effects of conventional polyethylene and biodegradable polylactic acid microplastics on earthworms in two different soil types. Both types of microplastic caused oxidative stress and altered gut microbiota in earthworms, with toxicity increasing at higher concentrations. The study found that microplastic concentration was more important than the type of plastic or soil in determining the level of harm, and that biodegradable plastics were not necessarily safer for soil organisms.
Microplastics originated from agricultural mulching films affect enchytraeid multigeneration reproduction and soil properties
This study tested microplastics from real agricultural mulching films, both conventional polyethylene and biodegradable types, on small soil worms over multiple generations. Even biodegradable film microplastics reduced worm reproduction and altered soil properties like pH and water-holding capacity. The results show that microplastics from agricultural plastics, including supposedly eco-friendly alternatives, can harm soil organisms and threaten long-term soil health and food production.
The impact of microplastic on nematodes: Soil type, plastic amount and aging as determinants for the fitness of Caenorhabditis elegans
Researchers tested how two types of microplastics, conventional polyethylene and biodegradable PLA/PBAT, affected tiny soil worms called nematodes across different soil types. Conventional plastic at high concentrations reduced worm reproduction and growth, while the biodegradable plastic caused no harm. Importantly, as microplastics aged in the soil over time, their negative effects worsened, suggesting the long-term impact of plastic pollution in agricultural soil may be greater than short-term studies indicate.
Biodegradable microplastics exert differential impacts from polyethylene on pesticide fate in soil-earthworm systems: insights into degradation selectivity and microbial mechanisms
This study compared how conventional polyethylene and biodegradable polylactic acid (PLA) microplastics affect pesticide behavior in soil with earthworms. Researchers found that PLA at high concentrations actually accelerated pesticide breakdown and increased the accumulation of pesticide byproducts in earthworms by up to 82%, while also causing oxidative stress and gut bacteria disruption, suggesting biodegradable plastics may pose their own set of environmental risks.
Microplastic particles reduce reproduction in the terrestrial worm Enchytraeus crypticus in a soil exposure
Researchers exposed terrestrial worms (Enchytraeus crypticus) to nylon and PVC microplastic particles of different sizes in soil. They found that while survival was unaffected, reproduction was significantly reduced at high concentrations, with smaller particles causing greater reproductive harm than larger ones. The study demonstrates that microplastic particle size is an important factor in determining toxicity to soil organisms, with implications for assessing environmental risk in terrestrial ecosystems.