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61,005 resultsShowing papers similar to Succession of soil bacterial communities and network patterns in response to conventional and biodegradable microplastics: A microcosmic study in Mollisol
ClearThe plastisphere of biodegradable and conventional microplastics from residues exhibit distinct microbial structure, network and function in plastic-mulching farmland
Researchers compared the bacterial communities that colonize biodegradable and conventional plastic microplastics in farmland soil. They found that biodegradable plastics (PBAT/PLA) and conventional polyethylene each attracted distinct microbial communities with different functions, including bacteria that could degrade plastics or cycle nutrients. The results suggest that even biodegradable plastics create unique microbial environments in soil that may affect soil health and function in unexpected ways.
Biodegradable Polyesters and Low Molecular Weight Polyethylene in Soil: Interrelations of Material Properties, Soil Organic Matter Substances, and Microbial Community
Researchers examined how biodegradable polyesters and low molecular weight polyethylene behave in soil environments, investigating their interactions with soil organic matter and microbial communities over time. They found that both biodegradable and conventional polymer microplastics alter soil microbial community composition and interact with organic matter fractions, with biodegradable plastics showing distinct but not necessarily more benign effects than conventional plastics.
Deciphering the Mechanisms Shaping the Plastisphere Microbiota in Soil
Researchers characterized bacterial communities colonizing biodegradable and conventional microplastics in soil, finding that polymer type and biodegradability shaped distinct plastisphere communities, with deterministic processes playing a stronger role in community assembly than in surrounding soil.
Microplastics increase soil microbial network complexity and trigger diversity-driven community assembly
Researchers found that microplastics in soil increased bacterial network complexity and shifted microbial community assembly in a diversity-dependent manner, with high-density polyethylene causing more harm to plant growth than polystyrene or polylactic acid particles.
Differential responses of soil microbial community structure and function to conventional and biodegradable microplastics
Scientists compared how tiny pieces of regular plastics and "biodegradable" plastics affect helpful bacteria in soil after 6 months. They found that biodegradable plastics actually disrupted soil bacteria more than regular plastics, changing the microbes that help plants grow and cycle nutrients. This matters because these soil bacteria are crucial for growing healthy food, so switching to biodegradable plastics might not be the simple environmental solution we hoped for.
Soil biota modulate the effects of microplastics on biomass and diversity of plant communities
Researchers used mesocosm experiments with natural soil biota to compare the effects of biodegradable and non-biodegradable microplastics on plant community biomass and diversity. Soil biota modulated the impact of microplastics, with biodegradable plastics showing similar effects to conventional plastics on plant community structure, challenging the assumption that biodegradable alternatives are environmentally benign.
LDPE microplastics significantly alter the temporal turnover of soil microbial communities
Soil amended with polyethylene microplastics showed a significantly faster rate of bacterial community succession over time compared to unamended controls, with community differences between plastic and control soils increasing linearly with incubation duration. The results suggest microplastics accelerate microbial turnover in terrestrial ecosystems, with potential consequences for soil stability and function.
Biodegradable and conventional microplastics exhibit distinct microbiome, functionality, and metabolome changes in soil
Researchers compared the effects of conventional plastics (polyethylene and polystyrene) and biodegradable plastics (polylactide and polybutylene succinate) on soil microbial communities. They found that both types of microplastics significantly altered soil microbial composition, but biodegradable microplastics had a more pronounced impact on soil metabolic function and microbial activity than conventional ones.
Investigation of Soil-Dwelling Bacterial Community Changes Induced by Microplastic Ex posure Using Amplicon Sequencing
Researchers analyzed soil bacterial community composition after microplastic contamination, finding that different polymer types caused distinct shifts in microbial diversity and functional groups, with implications for soil nutrient cycling and agricultural productivity.
The Structural and Functional Responses of Rhizosphere Bacteria to Biodegradable Microplastics in the Presence of Biofertilizers
Researchers studied how biodegradable microplastics interact with biofertilizers in crop soils and found that even though biodegradable plastics are designed as greener alternatives, they still significantly altered soil bacterial communities and disrupted carbon metabolism pathways. The findings suggest that biodegradable microplastics may affect soil health differently than conventional plastics, but are not necessarily harmless.
The Succession of Bacterial Community Attached on Biodegradable Plastic Mulches During the Degradation in Soil
Researchers studied how bacterial communities colonize and change over time on biodegradable plastic mulches buried in soil for five months. The study found that plastic composition and incubation time significantly shaped microbial communities, and notably, potential pathogens were detected at higher levels on biodegradable plastics compared to conventional polyethylene mulch.
Insights into soil microbial assemblages and nitrogen cycling function responses to conventional and biodegradable microplastics
Researchers compared how biodegradable polylactic acid and conventional PVC microplastics affect soil bacteria and nitrogen cycling processes. They found that both types of microplastics altered microbial communities, but biodegradable plastics had distinct effects on nitrogen-processing bacteria and did not simply behave as a harmless alternative. The study suggests that switching to biodegradable plastics may change rather than eliminate the impact of microplastic contamination on soil health.
Microplastic effects on soil organic matter dynamics and bacterial communities under contrasting soil environments
Researchers compared microplastic effects on soil organic matter dynamics and bacterial communities across contrasting soil environments, finding that the type of microplastic polymer and soil conditions together determine whether microbial activity and carbon cycling are stimulated or suppressed.
Discrepant soil microbial community and C cycling function responses to conventional and biodegradable microplastics
Scientists compared how conventional polyethylene and biodegradable polylactic acid microplastics affect soil microbial communities and carbon cycling. Researchers found that the two types of microplastics had markedly different effects, with biodegradable plastics causing more changes to microbial community structure and carbon-related gene activity. The study suggests that biodegradable plastics, while designed to be more environmentally friendly, may still significantly alter soil biology.
Distinct influence of conventional and biodegradable microplastics on microbe-driving nitrogen cycling processes in soils and plastispheres as evaluated by metagenomic analysis
Researchers compared how conventional polyethylene and biodegradable microplastics affect nitrogen cycling by soil microbes. They found that biodegradable microplastics caused stronger changes to microbial communities and nitrogen processing pathways than conventional plastics, particularly by enriching certain bacteria on their surfaces. The study suggests that even biodegradable plastic mulch alternatives may significantly alter soil nutrient cycling in agricultural settings.
Effect of LDPE and biodegradable PBAT primary microplastics on bacterial community after four months of soil incubation
Researchers compared the effects of conventional polyethylene (LDPE) and biodegradable PBAT microplastics on soil bacterial communities over four months. They found that both types of microplastics altered soil microbial community composition, but PBAT had a more pronounced effect due to its biodegradability providing additional carbon sources. The study suggests that biodegradable plastics are not necessarily safer for soil ecosystems than conventional plastics.
Effects of microplastics on soil microbiome: The impacts of polymer type, shape, and concentration
Researchers examined how different microplastic polymer types, shapes, and concentrations affected soil bacterial communities, finding that these physical characteristics induced distinct shifts in soil microbiome composition and diversity.
Bacterial life-history trade-offs under biodegradable and conventional microplastics in cinnamon and lime concretion black soils
Researchers studied how two biodegradable and four conventional microplastics affect bacterial life-history trade-offs in two distinct Chinese soil types, finding that soil type and plastic type together shaped bacterial diversity, community composition, and functional profiles.
Microplastics in soil ecosystems: soil fauna responses to field applications of conventional and biodegradable microplastics
Researchers conducted a field experiment comparing the effects of conventional polyethylene and polypropylene microplastics with biodegradable polylactic acid and polybutylene succinate microplastics on soil fauna communities, finding no significant effects on community composition after 40 days at any concentration tested.
Regulatory path for soil microbial communities depends on the type and dose of microplastics
Researchers compared how six types of microplastics at different concentrations affect soil microbial communities, testing both conventional and biodegradable plastics. They found that biodegradable microplastics had a greater impact on soil carbon and nitrogen levels than conventional ones, and that the type and dose of microplastic determined which microbial groups were most affected. The findings suggest that even so-called biodegradable plastics can significantly alter soil ecosystems when they break down into microplastic-sized particles.
Changes in bacterial community structures in soil caused by migration and aging of microplastics
A 90-day soil column experiment tracked the downward migration of polystyrene and polypropylene microplastics through soil layers, finding that MPs moved progressively deeper over time while undergoing surface chemical changes including increased hydrophilicity. MP migration significantly altered bacterial diversity patterns in soil layers relative to MP-free controls, with colonized MPs hosting distinct communities from surrounding soil.
Independent and combined effects of microplastics pollution and drought on soil bacterial community
Researchers studied how polyethylene and polylactic acid microplastics, combined with drought conditions, affect soil bacteria. Very small (20 micrometer) biodegradable PLA microplastics significantly reduced bacterial diversity by over 17%, while conventional polyethylene had less impact. The results suggest that the combined stress of microplastic pollution and drought could meaningfully alter soil microbial communities that are essential for healthy ecosystems and agriculture.
Time-dependent effects of microplastics on soil bacteriome
Researchers studied how six common types of microplastics affect soil bacteria over time at realistic contamination levels. The effects were slow to appear due to the chemical stability of plastics, but over time, microplastics altered bacterial community structure and soil functions in ways that differed by plastic type. This matters because changes to soil bacteria can affect nutrient cycling and crop health, with potential downstream effects on food quality.
Biodegradable microplastics enhance soil microbial network complexity and ecological stochasticity
Researchers found that biodegradable microplastics increased soil microbial network complexity and shifted community assembly toward more stochastic processes, suggesting they reshape soil ecosystems differently than conventional plastics.