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61,005 resultsShowing papers similar to Microplastics in Motion: How Earthworm Guts Become Microbial Gateways through Plastic Surface Dynamics
ClearEarthworms Exposed to Polyethylene and Biodegradable Microplastics in Soil: Microplastic Characterization and Microbial Community Analysis
Researchers exposed earthworms to biodegradable and conventional polyethylene microplastics in natural soil and found that worms ingested both types. The biodegradable plastic showed signs of partial breakdown in the earthworm gut, while conventional polyethylene remained unchanged. Although microplastics did not significantly alter the soil or gut microbiome in this study, the results confirm that earthworms transport microplastics through soil ecosystems.
The effects of high-density polyethylene and polypropylene microplastics on the soil and earthworm Metaphire guillelmi gut microbiota
Researchers exposed earthworms to soil amended with high-density polyethylene and polypropylene microplastics for 28 days and examined changes in both the earthworm gut and soil microbial communities. They found that both types of microplastics significantly altered the composition and diversity of gut bacteria in the earthworms. The study suggests that microplastic contamination in soil can disrupt the gut microbiota of soil organisms, with potential consequences for soil ecosystem health.
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.
Fragmentation and depolymerization of microplastics in the earthworm gut: A potential for microplastic bioremediation?
Researchers explored whether earthworms can break down microplastics in soil by passing them through their digestive systems. They found that earthworms fragmented and partially broke down polyethylene and biodegradable plastic particles, reducing their size and altering their chemical structure. This suggests earthworms could play a role in naturally reducing microplastic contamination in soil, though more research is needed to understand whether the smaller fragments pose their own risks.
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.
Earthworm-microbiome interactions: Unlocking next-generation bioindicators and bioengineered solutions for soil and environmental health
This review explores how earthworms and their associated microbiomes can serve as bioindicators of soil contamination from pollutants including microplastics. Changes in earthworm gut microbial communities can act as early warning signals of soil pollution, and engineered earthworm-microbiome systems show potential for environmental remediation. The study suggests that understanding these biological interactions could lead to new biomonitoring tools for assessing microplastic contamination in terrestrial ecosystems.
Incorporation of microplastics from litter into burrows of Lumbricus terrestris
Researchers investigated whether earthworms incorporate microplastics from surface litter into their burrows, finding that earthworm burrowing activity actively transports microplastics deeper into the soil profile.
Effects of farmland residual mulch film-derived microplastics on the structure and function of soil and earthworm Metaphire guillelmi gut microbiota
This study examined how microplastics from agricultural plastic mulch films affect soil and earthworm gut bacteria. Researchers found that aged microplastics from used farm films had different effects on microbial communities compared to new plastic particles, disrupting the normal bacterial networks in both soil and earthworm digestive systems.
Decay of low-density polyethylene by bacteria extracted from earthworm's guts: A potential for soil restoration
Researchers isolated bacteria from earthworm guts that were able to degrade low-density polyethylene, demonstrating that intestinal microbes from soil invertebrates may play a role in plastic breakdown. The findings suggest that earthworm gut microbiomes are a reservoir of plastic-degrading bacteria with potential applications for bioremediation of LDPE-contaminated soils.
Earthworm Casting Drives Soil Microplastic Upward Transport and the Formation of Biogenic Polymer Aggregates
Scientists found that earthworms are moving tiny plastic particles (microplastics) from deeper soil up to the surface, where crops grow, and breaking them into even smaller pieces in the process. The earthworms also create conditions that help beneficial bacteria break down these plastics over time. This matters because it could affect how much plastic contamination gets into our food supply, though more research is needed to understand the full health implications.
Microplastics exert minor influence on bacterial community succession during the aging of earthworm (Lumbricus terrestris) casts
Researchers exposed earthworms to three types of microplastics commonly used in agricultural films and found that while microplastics altered some soil chemistry during gut passage, they had only minor effects on the overall bacterial communities in earthworm castings over 180 days. This suggests that earthworm gut microbiomes may be resilient enough to buffer the impact of agricultural microplastic contamination under the conditions tested.
Microplastic transport in soil by earthworms
Researchers demonstrated that earthworms can transport microplastic particles from the soil surface deeper into the ground, with smaller particles being moved to greater depths. Using the common earthworm Lumbricus terrestris in greenhouse experiments, they showed that worm activity significantly increased the presence of microplastics in lower soil layers. The findings suggest that earthworms play an important role in burying microplastics in soil, potentially affecting other soil organisms and groundwater.
Effect of microplastic pollution on the gut microbiome of anecic and endogeic earthworms
Researchers investigated how low-density polyethylene microplastic pollution affects the gut microbiome of two types of earthworms with different burrowing lifestyles. They found that microplastics altered the relative abundance of several bacterial groups in both species, with deeper-burrowing anecic earthworms showing more pronounced effects and reduced survival. The study suggests that microplastic contamination in soil may disrupt the gut microbial communities of earthworms, with impacts varying by species and ecological behavior.
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.
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.
Pivotal role of earthworm gut protists in mediating antibiotic resistance genes under microplastic and sulfamethoxazole stress in soil–earthworm systems
Researchers found that gut protists in earthworms play a pivotal role in mediating the spread of antibiotic resistance genes when earthworms are co-exposed to microplastics and antibiotics in soil, identifying a previously overlooked biological pathway for AMR dissemination.
Polyvinyl chloride microplastic triggers bidirectional transmission of antibiotic resistance genes in soil-earthworm systems
This study found that PVC microplastics in soil trigger a two-way spread of antibiotic resistance genes between earthworm guts and the surrounding soil. The microplastics increased both the diversity and abundance of these resistance genes, with the transfer happening through bacteria sharing genetic material. This is concerning because earthworms are essential for soil health, and microplastics may be turning soil ecosystems into breeding grounds for antibiotic-resistant bacteria.
Microplastic digestion generates fragmented nanoplastics in soils and damages earthworm spermatogenesis and coelomocyte viability
Researchers discovered that earthworms can fragment polyethylene microplastics into even smaller nanoplastics through their digestive process in soil. The study also found that microplastic exposure damaged earthworm reproductive cells and immune cells, suggesting that the biological breakdown of microplastics in soil creates smaller particles that may be even more concerning for ecosystem health.
Current Research Trends on the Effects of Microplastics in Soil Environment Using Earthworms: Mini-Review
This mini-review summarizes current research on how microplastics affect earthworms in soil environments, covering effects on growth, reproduction, gut microbiota, and soil physicochemical properties.
Microplastics in Agricultural Soil: Fate, Impacts, and Bioremediation by Earthworms
This review examines how microplastics accumulate in agricultural soils and the role earthworms may play in breaking them down. Researchers found that microplastics can harm soil health by disrupting microbial communities, enzyme activity, and nutrient availability, but that earthworms can enhance microplastic degradation through their digestive processes and the microorganisms in their gut. The study suggests that earthworm-based bioremediation could be a practical strategy for reducing microplastic contamination in farmland.
Leaching of microplastics by preferential flow in earthworm (Lumbricus terrestris) burrows
This study showed that earthworms can ingest microplastics from soil surfaces and transport them through their burrows into deeper soil layers via preferential flow pathways. The findings suggest earthworm activity contributes to the vertical movement of microplastics through soil profiles, with implications for groundwater contamination.
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.
Earthworms Significantly Alter the Composition, Diversity, Abundance and Pathogen Load of Fungal Communities in Sewage Sludge from Different Urban Wastewater Treatment Plants
Earthworms exposed to microplastic-contaminated soil were found to significantly alter the composition, diversity, and abundance of potentially pathogenic soil bacteria, suggesting that earthworm bioturbation in MP-contaminated soils may have unintended effects on soil microbiome health.
Enhancing microplastic removal and nitrogen mitigation in constructed wetlands: An earthworm-centric perspective
Researchers added earthworms to constructed wetlands and found they significantly improved the removal of biodegradable microplastics and nitrogen pollutants from wastewater. The earthworms reshaped their gut microbial communities in ways that boosted both plastic degradation and nitrogen cycling, increasing microplastic removal by 13.5 percent. The findings suggest that incorporating earthworms into wetland treatment systems could offer a natural, low-cost approach to improving water quality.