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61,005 resultsShowing papers similar to PET particles raise microbiological concerns for human health while tyre wear microplastic particles potentially affect ecosystem services in waters
ClearImpact of Microplastic on Freshwater Sediment Biogeochemistry and Microbial Communities Is Polymer Specific
Researchers used a microcosm approach to test how three common plastic types found in Great Lakes sediments affect freshwater benthic biogeochemistry and microbial communities. They found that each polymer had distinct effects: PET fibers decreased ecosystem metabolism, PVC particles increased nutrient uptake, and tire-derived rubber most substantially altered microbial community function. The study highlights that the environmental impact of microplastics in freshwater sediments depends heavily on the specific polymer type involved.
The difference between tire wear particles and polyethylene microplastics in stormwater filtration systems: Perspectives from aging process, conventional pollutants removal and microbial communities
Researchers compared how tire wear particles and polyethylene microplastics behave in stormwater filtration systems used to treat urban runoff. They found that tire wear particles leached more toxic chemicals and supported different microbial communities than conventional microplastics, leading to distinct effects on pollutant removal. The study highlights that tire wear particles deserve separate consideration from other microplastics when designing stormwater treatment infrastructure.
Biomass formation and organic carbon migration potential of microplastics from a PET recycling plant: Implication of biostability
PET microplastics from a recycling plant promoted bacterial growth in freshwater, with particles smaller than 100 microns supporting up to 1.05 x 10^9 bacteria per gram and shifting microbial diversity by favoring Burkholderiaceae, highlighting pollution risks from the mechanical PET recycling industry.
Tire wear particles in different water environments: occurrence, behavior, and biological effects—a review and perspectives
This review examines tire wear particles, a major but often overlooked source of microplastics in water environments. Tire particles release toxic chemicals as they break down in water and can harm aquatic organisms, but most research has focused only on the chemical leachate rather than the particles themselves. Since tire wear contributes a large share of total microplastic pollution, understanding its full impact on water ecosystems and the food chain is important for human health.
A comparative analysis of the chemical composition and biofilm formation on tire wear particles from six different tire types
Researchers analyzed the chemical composition and biofilm communities forming on tire-wear particles compared to other microplastic types, finding that tire wear particles support distinct microbial assemblages. The unique surface chemistry of tire wear particles may promote the attachment of pathogens and toxin-producing microorganisms.
Size-dependent ecotoxicological impacts of tire wear particles on zebrafish physiology and gut microbiota: Implications for aquatic ecosystem health
Researchers found that tire wear particles, a major but often overlooked source of microplastic pollution, affect zebrafish health differently depending on particle size. Smaller particles caused more severe gut microbiome disruption, oxidative stress, and immune responses, suggesting that tire-derived microplastics in waterways may pose a greater health risk to aquatic life than previously recognized.
Microplastic biofilm in fresh- and wastewater as a function of microparticle type and size class
Researchers compared the biofilm communities that form on microplastics of different types and sizes in both freshwater and wastewater, finding that biofilm composition was influenced by particle type, size, and water source. These findings advance understanding of the plastisphere — the microbial community unique to plastic surfaces — and its potential role in spreading microorganism-associated risks.
Microplastics in freshwaters: Comparing effects of particle properties and an invertebrate consumer on microbial communities and ecosystem functions
Researchers tested how different microplastic properties, including concentration, shape, and polymer type, affect microbial communities and ecosystem functions in freshwater environments. They found that the presence of an invertebrate consumer had a stronger influence on microbial activity than the microplastics themselves, though high concentrations of certain particle shapes did alter community composition. The study suggests that the ecological effects of microplastics in freshwater depend heavily on the broader biological context.
Bacterial community colonization on tire microplastics in typical urban water environments and associated impacting factors
Researchers used 16S rDNA high-throughput sequencing to characterize bacterial community dynamics colonizing tire microplastics from three different tire brands and sizes in two urban water environments, including a constructed wetland influent pond. The study identified how tire microplastics support distinct and potentially harmful bacterial communities influenced by environmental conditions.
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.
Microbial community shifts induced by plastic and zinc as substitutes of tire abrasion
Researchers tested the effects of plastic particles and zinc separately on a freshwater microeukaryotic community using high-throughput 18S rRNA sequencing, using these as surrogates for tire wear particle components. Both plastic and zinc individually altered community composition at environmentally realistic concentrations, with plastic causing more pronounced shifts in community structure.
Contrasting the effects of microplastic types, concentrations and nutrient enrichment on freshwater communities and ecosystem functioning
Researchers tested two types of microplastics, conventional polyethylene and biodegradable polylactic acid, in outdoor freshwater mesocosms and found that neither type significantly affected community composition or ecosystem functions like algae growth and leaf decomposition. Even at concentrations known to cause harm in lab settings, the microplastics had minimal impact when tested in more realistic ecological conditions. The study suggests that real-world microplastic effects on freshwater communities may differ from laboratory predictions.
Tire wear particles drive size-dependent loss of freshwater bacterial biofilm diversity
Researchers placed tire wear particles of different sizes and types in the River Rhine for four weeks and studied the bacterial communities that formed on them. They found that tire wear particles supported significantly less diverse bacterial communities compared to natural river sediment, with larger particles reducing diversity even further. The study reveals that the widespread release of tire wear particles into freshwater systems may be reshaping microbial ecosystems by favoring certain specialized bacteria over others.
Anthropogenic Litter in Urban Freshwater Ecosystems: Distribution and Microbial Interactions
Researchers quantified anthropogenic litter in urban rivers and streams and found that microplastics dominated by mass and particle count compared to macroplastic items. The study highlights urban freshwater systems as major conduits for plastic pollution moving toward marine environments and documents distinct microbial communities on plastic surfaces.
Microplastics increase impact of treated wastewater on freshwater microbial community
Microplastic particles added to treated wastewater effluent amplified the impact on freshwater microbial communities compared to effluent alone, disrupting both bacterial community composition and functional processes. The study suggests that microplastics in treated wastewater discharge may compound the ecological harm caused by residual effluent contaminants on receiving water microbiology.
Not so dangerous? PET microplastics toxicity on freshwater microalgae and cyanobacteria
Researchers tested whether PET microplastics are toxic to freshwater algae and cyanobacteria and found that the effects were relatively mild compared to other plastic types. While PET particles did cause some changes in growth and photosynthesis at high concentrations, the organisms largely tolerated the exposure. The study suggests that not all microplastics are equally harmful, and PET may pose lower risks to aquatic primary producers.
Comparative analysis of microplastic and microbial communities in varied aquatic environments: Disparities in occurrence, interconnections, and ecological implications
Comparative surveys of microplastics and associated microbial communities across river, reservoir, and bay environments in the Dongjiang watershed found that MP abundance and microbial community composition differed significantly by water type, with MP surfaces hosting distinct microbial assemblages.
Deciphering the pathogenic risks of microplastics as emerging particulate organic matter in aquatic ecosystem
Researchers compared how microplastics and natural organic matter like leaves and algae affect bacterial communities in aquatic environments. The study found that microplastics uniquely promoted pathogenic bacteria as keystone species and amplified their capacity to host antibiotic resistance genes, suggesting that microplastic pollution may pose distinct pathogenic risks beyond those of natural particles.
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.
Microbiomes on microplastics versus natural microcarriers: Stability and transformation during aquatic travel from aquaculture ponds to adjacent stream
Researchers compared microbial communities that form on microplastics versus natural materials as they travel from aquaculture ponds to adjacent streams. They found that different plastic types harbored distinct microbial communities, and that these plastisphere communities were less stable than those on natural substrates during transit between water bodies. The study suggests that microplastics may spread different assemblages of microorganisms as they move through connected aquatic environments.
Microbial Dynamics on Different Microplastics in Coastal Urban Aquatic Ecosystems: The Critical Roles of Extracellular Polymeric Substances
Researchers investigated how microbial communities colonize different types of microplastics in urban coastal waters, forming distinct ecosystems known as plastispheres. They found that the type of plastic significantly shaped which bacteria grew on it and how much sticky extracellular material they produced. Understanding these microbial communities on microplastics matters because they can harbor harmful bacteria and influence how pollutants move through aquatic environments.
Distinct microbial metabolic activities of biofilms colonizing microplastics in three freshwater ecosystems
Biofilms growing on microplastics in three freshwater ecosystems showed distinct patterns of carbon metabolism compared to biofilms on glass, with PET-colonizing biofilms showing lower metabolic diversity. Environmental factors like nutrient levels and turbidity also shaped biofilm function, suggesting microplastics alter microbial-mediated carbon cycling in rivers and lakes.
The ecology of the plastisphere: Microbial composition, function, assembly, and network in the freshwater and seawater ecosystems
Researchers studied the communities of bacteria and fungi that colonize microplastic surfaces in freshwater and seawater, forming what scientists call the plastisphere. These microplastic-associated communities were distinctly different from those in surrounding water, and included a higher proportion of disease-causing organisms and species involved in pollutant degradation. The findings suggest that microplastics create new habitats that can harbor pathogens and alter natural microbial ecosystems in ways that may affect water quality and human health.
Effects of microplastics on greenhouse gas emissions and microbial communities in sediment of freshwater systems
Researchers found that PET microplastics of different sizes significantly affected greenhouse gas emissions and microbial communities in freshwater sediments, with smaller particles (5 micrometers) notably increasing methane emissions and altering nutrient cycling over 90 days.