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61,005 resultsShowing papers similar to Biodegradability of microplastics reshapes surface biofilm microbial community structure and nitrogen cycling functions in aquatic environments
ClearInsights 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.
Effects of microplastics on nitrogen and phosphorus cycles and microbial communities in sediments
Researchers found that PVC, PLA, and polypropylene microplastics altered nitrogen and phosphorus cycling in freshwater sediments by shifting microbial community composition, with effects varying by polymer type and biodegradability.
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.
Microplastic exposure drives divergent assembly mechanisms in riverine microorganisms: Poly(butylene adipate-co-terephthalate) triggers metabolic shifts vs polyethylene-enhanced network complexity
Researchers compared how conventional polyethylene and biodegradable PBAT microplastics affect microbial communities in river water over 60 days. They found that both types significantly altered bacterial diversity, but through different mechanisms: PBAT triggered metabolic shifts in microorganisms while polyethylene increased the complexity of microbial networks. The study suggests that even biodegradable plastics can meaningfully disrupt aquatic microbial ecosystems.
Divergent biofilm colonization on plastics in wastewater: Accelerated maturation on polyamide versus growth inhibition on biodegradable polymers
Researchers tracked 30-day biofilm formation on three plastic types in simulated wastewater, finding that polyamide promoted rapid, robust microbial colonization via nitrogen enrichment, while biodegradable PBAT/PLA plastic initially attracted bacteria but then inhibited sustained growth due to toxic leachates — demonstrating that plastic chemistry shapes plastisphere ecology in wastewater treatment.
Microbial colonizers of microplastics in an Arctic freshwater lake
Researchers characterized the microbial communities that colonize biodegradable and non-biodegradable microplastics deployed in an Arctic freshwater lake over eleven days. The study found that the plastisphere microbial community was complex and differed from the surrounding water, with biodegradable plastic attracting distinct bacterial groups, suggesting that microplastic type influences which microorganisms colonize these particles in pristine environments.
Microplastic biofilms as potential hotspots for plastic biodegradation and nitrogen cycling: a metagenomic perspective
Researchers used genetic analysis to study the microbial communities that form biofilms on different types of microplastics in an estuarine environment. They found that these plastic-associated communities contained genes for both plastic degradation and nitrogen cycling, suggesting the biofilms may play dual roles in the ecosystem. The study indicates that microplastic surfaces in waterways create unique microbial habitats that could influence both pollution breakdown and nutrient processing.
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.
Differential responses of bacterial and archaeal communities to biodegradable and non-biodegradable microplastics in river
A 14-day microcosm experiment compared bacterial and archaeal community responses to biodegradable PLA and non-biodegradable PVC microplastics in river water using metagenomics. Both microplastic types selectively enriched distinct microbial assemblages, with archaeal communities more sensitive to colonization time than bacterial communities, and PLA fostering distinct biodegrading taxa.
The 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.
Distinctive patterns of bacterial community succession in the riverine micro-plastisphere in view of biofilm development and ecological niches
Scientists studied how bacterial communities develop on microplastics versus natural materials in river water and found that plastics support a distinct pattern of microbial colonization. The research identified specific bacteria capable of degrading microplastics and revealed that competition among microbes on plastic surfaces follows unexpected patterns compared to natural substrates.
Comparison of pristine and aged poly-L-lactic acid and polyethylene terephthalate as microbe carriers in surface water: Displaying apparent differences
Researchers compared how pristine and UV-aged biodegradable poly-L-lactic acid and non-degradable PET microplastics serve as carriers for microbial communities in river water. They found that aged microplastics attracted more microbes and had higher biofilm formation than pristine ones, and that the biodegradable PLLA supported greater microbial enrichment and diversity than PET. The study demonstrates that microplastics in aquatic environments are highly effective carriers for bacteria, including pathogens and antibiotic resistance genes.
Traditional and biodegradable plastics host distinct and potentially more hazardous microbes when compared to both natural materials and planktonic community
Researchers compared the bacterial communities that colonize traditional plastics, biodegradable plastics, and natural materials like wood and glass in freshwater environments. They found that both conventional and biodegradable plastics hosted distinct and potentially more hazardous microbial communities than natural materials. The study suggests that biodegradable plastics are not necessarily safer from a microbial perspective and may still serve as platforms for harmful bacteria in the environment.
Ecological implications of biodegradable and conventional microplastics: Dissolved organic matter bioavailability and microbial response in marine systems
Researchers compared the dissolved organic matter released by biodegradable and conventional microplastics and assessed its bioavailability to marine microbial communities. They found that biodegradable plastics like PLA released organic matter that was more readily used by microorganisms, which altered microbial community composition. The study suggests that while biodegradable plastics break down faster, their leached compounds may have distinct and potentially significant ecological effects in marine environments.
Response mechanism of non-biodegradable polyethylene terephthalate microplastics and biodegradable polylactic acid microplastics to nitrogen removal in activated sludge system
Researchers compared how non-biodegradable PET and biodegradable PLA microplastics affect nitrogen removal in wastewater treatment systems. Surprisingly, the biodegradable PLA caused a much larger reduction in ammonia removal efficiency than the conventional PET plastic. The study suggests that even biodegradable plastics can significantly disrupt the microbial processes that wastewater treatment plants rely on to clean water.
Effect of long-term exposure to non-biodegradable and biodegradable microplastics in continuous anoxic/aerobic bioreactors: Nitrogen removal performance, microbial communities and functional gene responses
Researchers compared the effects of biodegradable and non-biodegradable microplastics on nitrogen removal in wastewater treatment bioreactors over an extended period. They found that biodegradable polylactic acid particles were actually more harmful than conventional PET microplastics, significantly reducing the efficiency of ammonia removal by damaging beneficial bacteria. The study challenges the assumption that biodegradable plastics are always safer for wastewater treatment systems.
Unveiling the impact of microplastics with distinct polymer types and concentrations on tidal sediment microbiome and nitrogen cycling
Researchers tested how five different types of microplastics at varying concentrations affect microbial communities and nitrogen cycling in tidal sediments over 30 days. They found that microplastics generally reduced microbial diversity and enhanced nitrogen fixation, with biodegradable PLA plastic showing concentration-dependent effects. The study suggests that microplastic contamination in coastal sediments can disrupt important nutrient cycling processes driven by microorganisms.
Characteristics analysis of plastisphere biofilm and effect of aging products on nitrogen metabolizing flora in microcosm wetlands experiment
Researchers placed three types of plastic in miniature constructed wetlands for 180 days and tracked how they aged and affected microbial communities. The plastics degraded at different rates, with PVC developing new chemical groups and all surfaces becoming less water-repellent as bacteria colonized them. The plastic surfaces altered nitrogen-processing bacteria in the wetland water, suggesting microplastics can disrupt nutrient cycling in natural wetland ecosystems.
Polymer type and aging drive the selective enrichment of antibiotic resistance genes and pathogens in microplastics biofilms
Researchers compared how microorganisms colonize conventional polypropylene versus biodegradable polylactic acid microplastics in a wetland environment. They found that while biodegradable PLA attracted fewer total microbes, it actually enriched a higher proportion of antibiotic-resistant pathogens and resistance genes, especially after environmental aging. The findings raise important questions about whether biodegradable plastics may pose unexpected risks as carriers of antibiotic resistance in aquatic ecosystems.
The impacts of biodegradable and non-biodegradable microplastic on the performance and microbial community characterization of aerobic granular sludge
Researchers compared the effects of biodegradable polylactic acid microplastics and non-biodegradable polyethylene microplastics on aerobic granular sludge used in wastewater treatment. They found that high concentrations of both types impaired the sludge's ability to remove organic pollutants, but both actually enhanced nitrogen and phosphorus removal at moderate levels. The study reveals that even biodegradable microplastics can disrupt wastewater treatment processes in unexpected ways.
Land Use Rather than Microplastic Type Determines the Diversity and Structure of Plastisphere Bacterial Communities
Researchers compared bacterial communities that form on conventional polyethylene versus biodegradable polylactic acid microplastics across four different land use types. They found that land use -- whether the soil came from vegetable fields, orchards, rice paddies, or woodlands -- had a much greater influence on which bacteria colonized the plastic surfaces than the type of plastic itself. The study suggests that simply switching to biodegradable plastics may not significantly change the microbial communities associated with plastic pollution in soils.
Distinct microbial community structures formed on the biofilms of PLA and PP, influenced by physicochemical factors of sediment and polymer types in a 60-day indoor study
This 60-day lab study compared the microbial communities that grow on traditional polypropylene microplastics versus biodegradable polylactic acid (PLA) microplastics in sediment. Each plastic type attracted distinctly different bacterial communities, influenced by the plastic's properties and surrounding sediment chemistry. The findings suggest that even biodegradable plastic alternatives still alter microbial ecosystems in ways that could affect environmental and human health.
Biofilms in plastisphere from freshwater wetlands: Biofilm formation, bacterial community assembly, and biogeochemical cycles
Researchers studied how bacteria form biofilms on microplastic surfaces in freshwater wetlands and found that these plastic-associated communities differ significantly from natural soil bacteria. The microplastic biofilms had lower diversity but higher activity in carbon processing and nitrogen cycling genes. This means microplastics in wetlands can alter natural nutrient cycles, potentially affecting water quality in ecosystems that many communities rely on.
Microplastic induces microbial nitrogen limitation further alters microbial nitrogentransformation: Insights from metagenomic analysis
Researchers studied how both conventional and biodegradable microplastics affect nitrogen cycling in soil over 120 days. They found that biodegradable microplastics significantly disrupted microbial nitrogen processes by acting as a carbon source that shifted bacterial communities toward nitrogen-fixing species. The findings suggest that even biodegradable plastics in soil can alter nutrient availability in ways that may affect soil fertility and plant growth.