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61,005 resultsShowing papers similar to Alteration potential of Propylene microplastic on soil toxicity: impact of organic matter and aging of microplastics
ClearImpact of microplastics and aged microplastics on the toxicity of emerging contaminants in the soil
Researchers assessed how polypropylene (PP) microplastics and UV-aged PP microplastics modify the toxicity of eight emerging organic contaminants -- including diclofenac, ciprofloxacin, and diuron -- on soil organism Enchytraeus crypticus, finding that while PP alone had no effect at 5 mg/kg, its presence significantly amplified the toxicity of all tested organic pollutants.
The effect of polystyrene microplastic and biosolid application on the toxicity and bioaccumulation of cadmium for Enchytraeus crypticus
Researchers tested how polystyrene microplastics and biosolid application jointly affected cadmium toxicity and bioaccumulation in the soil worm Enchytraeus crypticus, finding that biosolid application altered metal availability in ways that modified the toxicity of cadmium under MP presence. The study highlights the complexity of predicting contaminant risks in agricultural soils with multiple amendment inputs.
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.
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.
Virgin and Photoaged Polyethylene Microplastics Have Different Effects on Collembola and Enchytraeids
Researchers compared how virgin and UV-aged polyethylene microplastics affect two types of small soil organisms at environmentally relevant concentrations. They found contrasting responses between species: one type showed reduced survival but increased reproduction with aged particles, while another showed the opposite pattern. The study highlights that microplastic aging and species differences both matter when assessing the ecological impact of plastic pollution in soils.
Influence of polyethylene-microplastic on environmental behaviors of metals in soil
Researchers investigated how polyethylene microplastics affect the adsorption, desorption, and bioavailability of heavy metals in soil. They found that adding microplastics altered how metals bind to soil particles and increased the mobility of certain metals like cadmium and lead. The study suggests that microplastic contamination in soils may change the environmental behavior of heavy metals, potentially increasing their availability to plants and soil organisms.
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.
Combined effects of microplastics and cadmium on the soil-plant system: Phytotoxicity, Cd accumulation and microbial activity
Researchers tested how different microplastic types combined with cadmium affect plant growth and soil health. Aged and biodegradable microplastics increased cadmium uptake in mustard greens more than fresh conventional plastics did. The study also found that microplastics altered soil microbial activity, suggesting that plastic pollution in farmland could change how plants absorb toxic metals from contaminated soil.
Influences of coexisting aged polystyrene microplastics on the ecological and health risks of cadmium in soils: A leachability and oral bioaccessibility based study
This study tested whether the presence of aged microplastics in soil changes how easily the toxic heavy metal cadmium can enter the human body through accidental soil ingestion. The results showed that aged polystyrene microplastics actually reduced cadmium absorption in the stomach phase, though the effect varied by soil type. This suggests that the interaction between microplastics and other pollutants in soil creates a complicated picture for assessing human health 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.
Polypropylene microplastics affect the distribution and bioavailability of cadmium by changing soil components during soil aging
A 180-day soil aging experiment with polypropylene microplastics at 2-10% concentration showed that microplastics altered the distribution of cadmium between soil particle-associated organic matter, organo-mineral complexes, and mineral fractions. Higher microplastic concentrations shifted cadmium toward more stable organo-mineral associations, reducing its bioavailability over time.
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.
The interaction effects of biodegradable microplastics and Cd on Folsomia candida soil collembolan
Researchers investigated the combined effects of biodegradable PLA microplastics and cadmium on the soil organism Folsomia candida, finding that microplastics altered cadmium bioavailability and their interaction produced distinct toxicological effects.
Interaction of microplastics with heavy metals in soil: Mechanisms, influencing factors and biological effects
This review summarizes how microplastics and heavy metals interact in soil, where microplastics can absorb and carry toxic metals through the food chain and into the human body. Aging and weathering of microplastics changes their surface properties, making them better at picking up heavy metals, which raises concerns about combined exposure through contaminated crops and water.
Altered interactions and joint toxicity between microplastics and zinc induced by activated sludge composting process
Researchers studied how the composting process ages microplastics made of PET, PP, and PE, and how this aging alters their interactions with the heavy metal zinc. They found that composting increased cracks and oxygen-containing groups on the plastic surfaces, enhancing their capacity to adsorb zinc and increasing the combined toxicity to the model organism C. elegans. The study suggests that aged microplastics in compost may increase heavy metal bioavailability when applied to agricultural soils.
Aging in soil increases the disturbance of microplastics to the gut microbiota of soil fauna
Researchers compared how fresh versus soil-aged microplastics affect the gut bacteria of small soil-dwelling worms called enchytraeids. They found that microplastics that had aged in soil for several months caused significantly greater disruption to the animals' gut microbiome than fresh particles. The aging process released chemical additives and encouraged biofilm growth on the plastic surfaces, making aged microplastics more biologically active and potentially more harmful to soil organisms.
Interactive effects of microplastics and typical pollutants on the soil-plant system: a mini-review
This review examines how microplastics interact with heavy metals and organic pollutants in soil and what that means for plant growth. Researchers found that certain plastic types can increase the availability of toxic metals like cadmium while also affecting how organic chemicals behave in soil. The study suggests that the combined presence of microplastics and other pollutants in agricultural soils may create compounding risks to crop health and food safety.
Ecotoxicological effects of polyethylene microplastics and lead (Pb) on the biomass, activity, and community diversity of soil microbes
A soil experiment found that polyethylene microplastics made lead (a toxic heavy metal) more available in soil and worsened its harmful effects on soil microorganisms. The combination reduced beneficial enzyme activity, lowered microbial efficiency, and shifted the soil microbial community, suggesting that microplastic pollution in contaminated soils could amplify heavy metal toxicity in ways that ultimately affect food crops and human health.
Aging enhancement and synergistic effect on toxicity to soil fauna by polystyrene microplastics-tetrabromobisphenol A toxicity exposure
Researchers investigated the combined toxicity of aged polystyrene microplastics and the flame retardant tetrabromobisphenol A on earthworms, finding that aging enhanced the microplastics' ability to adsorb and deliver the toxic chemical. The co-exposure produced synergistic effects including increased oxidative stress, gut microbiome disruption, and tissue damage beyond what either contaminant caused alone. The study highlights that weathered microplastics in contaminated soils may amplify the toxicity of co-occurring industrial chemicals.
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.
Sublethal effects of microplastics sourced from polypropylene agricultural plastics on four soil invertebrate species
Four soil invertebrate species were exposed to microplastics from polypropylene agricultural mulch at 0.005–5% concentrations in soil, finding reduced reproduction in enchytraeids and collembola and altered burrowing behavior in earthworms and isopods at higher doses.
Combined interactions and ecotoxicological effects of micro/nanoplastics and organic pollutants in soil–plant systems: a critical overview
This review examines how micro- and nanoplastics interact with organic pollutants in soil-plant systems. The study highlights that these plastic particles can act synergistically with organic pollutants in terrestrial ecosystems, posing combined threats to soil and plant health that warrant further investigation.
Microplastics Reduce the Negative Effects of Litter-Derived Plant Secondary Metabolites on Nematodes in Soil
Researchers found that microplastics in soil reduced the toxic effects of plant-derived chemicals (phenolic compounds from leaf litter) on soil nematodes. The microplastics appeared to absorb the plant chemicals, reducing their bioavailability to the worms. This shows that microplastics can change soil chemistry in unexpected ways, potentially altering how soil ecosystems function.
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.