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61,005 resultsShowing papers similar to Microplastic surface properties affect bacterial colonization in freshwater
ClearTemporal dynamics of bacterial colonization on five types of microplastics in a freshwater lake
Researchers submerged five types of microplastics in a freshwater lake for about a year to study how bacterial communities colonize their surfaces over time. They found that different plastic types attracted distinct microbial communities, which changed significantly across seasons. The study reveals that microplastics serve as unique habitats for bacteria in freshwater, potentially influencing nutrient cycling and ecosystem dynamics.
Lacustrine plastisphere: Distinct succession and assembly processes of prokaryotic and eukaryotic communities and role of site, time, and polymer types
Researchers investigated how microbial communities colonize different types of microplastic polymers in freshwater lakes. The study found that bacteria and single-celled organisms follow distinct assembly patterns on microplastic surfaces, with colonization time, location, and polymer type all influencing community composition. These findings suggest microplastics serve as carriers that can promote microbial spread in aquatic environments.
Environmental Factors Support the Formation of Specific Bacterial Assemblages on Microplastics
Researchers incubated polystyrene, polyethylene, and wooden pellets across marine and freshwater environments and found that environmental conditions — more than plastic type — drove the formation of specific bacterial communities on microplastics, with plastic-specific assemblages only emerging under certain conditions.
No trophy for the trophy? - How lake trophy impacts bacterial assemblages of biofilm on microplastic
A field experiment incubating microplastics in five lakes with different nutrient levels (trophy) found that bacterial biofilm composition on MPs was dominated by Proteobacteria and differed significantly from free-water communities, but lake trophy had limited influence on overall biofilm diversity. This suggests that plastic surfaces create a distinct microbial niche independent of the surrounding water quality, with implications for how plastic-associated bacteria spread through freshwater ecosystems.
Microbial biofilm formation and community structure on low-density polyethylene microparticles in lake water microcosms
Researchers investigated biofilm formation on low-density polyethylene microparticles in lake water microcosms, finding that microplastic surfaces supported distinct and dynamic microbial communities that differed from those in the surrounding water.
The Effect of Microplastics on Microbial Succession at Impaired and Unimpaired Sites in a Riverine System
Researchers compared microbial biofilm diversity on microplastic polymers and natural substrates at impaired and unimpaired riverine sites, examining how environmental nutrient loads, seasonality, and geography influence microbiome succession on plastic surfaces in freshwater ecosystems.
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.
Microplastic bacterial communities in the Bay of Brest: Influence of polymer type and size
Researchers analyzed bacterial communities growing on microplastics collected from a coastal bay in France and found that the type of polymer influenced which bacteria colonized the surface. Different plastics like polyethylene, polypropylene, and polystyrene each hosted distinct microbial communities, though particle size had less influence. The study reveals that microplastics in the ocean serve as unique habitats for bacteria, which could have implications for how pollutants and pathogens are transported through marine environments.
Comparative Analysis of Selective Bacterial Colonization by Polyethylene and Polyethylene Terephthalate Microplastics
Biofilm communities were compared on polyethylene and polyethylene terephthalate microplastics incubated in two freshwater bacterial communities, finding that the original water source bacteria largely determined biofilm composition rather than the plastic type. The study suggests that the plastisphere in freshwater systems reflects local microbial pools more than plastic-specific selection.
Long-term study of the bacterial colonization of polypropylene microplastics in a freshwater lake by optical and molecular methods
This long-term study monitored bacterial colonization on polypropylene microplastic surfaces in a freshwater environment over an extended period, tracking how the plastisphere community develops and changes over time. Long-term data on plastisphere development reveals that microplastic surfaces support distinct and evolving microbial communities that differ from surrounding water, potentially harboring pathogenic or antibiotic-resistant bacteria.
Plastic substrate and residual time of microplastics in the urban river shape the composition and structure of bacterial communities in plastisphere
Researchers conducted an in-site incubation experiment in an urban river using microplastics from three plastic product types (garbage bags, shopping bags, and plastic bottles), finding that both plastic substrate type and incubation time shaped the bacterial communities colonizing the plastisphere. Different plastic products harbored distinct microbial communities, with potential implications for the spread of plastic-associated microorganisms in urban freshwater.
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.
Colonization characteristics of bacterial communities on plastic debris: The localization of immigrant bacterial communities
Researchers investigated the colonization characteristics of bacterial communities on plastic debris in environmental settings, finding that the localization of immigrant bacterial communities on plastic surfaces reflects specific colonization dynamics distinct from random sampling effects.
Selective enrichment of bacterial pathogens by microplastic biofilm
Researchers incubated biofilms on microplastics and natural substrates in freshwater and found that microplastic surfaces selectively enriched bacterial pathogens and antibiotic resistance genes compared to rock and leaf surfaces. The study suggests that microplastics in waterways may serve as hotspots for harmful bacteria and contribute to the spread of antibiotic resistance in the environment.
Nascently generated microplastics in freshwater stream are colonized by bacterial communities from stream and riparian sources
Researchers examined bacterial colonization of different types of nascently generated microplastics through time in a freshwater stream ecosystem, finding that colonizing taxa and their degradative abilities varied based on microplastic polymer type and time of exposure.
Colonization characteristics and surface effects of microplastic biofilms: Implications for environmental behavior of typical pollutants
This review examines how bacteria colonize microplastic surfaces in water, forming biofilms that change how the plastics behave in the environment. These biofilms alter the surface properties of microplastics and affect how they absorb and transport heavy metals and other pollutants. Understanding biofilm formation on microplastics is important because it can make the particles more dangerous by concentrating toxic substances that could eventually enter the food chain.
Microbial colonization of microplastics in the Caribbean Sea
Researchers incubated six common plastic polymers in Caribbean waters for six weeks and found that bacterial biofilm communities were not significantly shaped by plastic type or exposure time, but eukaryotic communities (including distinctive diatom assemblages) were influenced by both factors. This suggests that microplastics act as selective habitats for some microbial groups but not others, with implications for understanding how plastics alter ocean microbial ecology.
From wastewater discharge to the beach: Survival of human pathogens bound to microplastics during transfer through the freshwater-marine continuum
Researchers investigated how human pathogens survive on microplastic surfaces as they travel from wastewater treatment plants through freshwater into marine environments. They found that the biofilm environment on plastic surfaces helped bacteria like E. coli and Enterococcus faecalis persist longer during transitions between water types compared to bacteria in the surrounding water. The study suggests that microplastics may facilitate the environmental spread of pathogens by providing a protective habitat during transport.
Assessment of Emerging Pathogens and Antibiotic Resistance Genes in the Biofilm of Microplastics Incubated Under a Wastewater Discharge Simulation
Researchers incubated common plastic types in flowing water that simulated wastewater discharge conditions for 10 weeks and studied the bacteria that colonized the plastic surfaces. They found that microplastics exposed to treated wastewater developed distinct bacterial communities compared to those in clean river water, including emerging pathogens and antibiotic resistance genes. The study suggests that microplastics in waterways receiving wastewater may serve as mobile platforms for spreading harmful bacteria and antibiotic resistance in the environment.
Influence of biofilms on the adsorption behavior of nine organic emerging contaminants on microplastics in field-laboratory exposure experiments
Researchers studied how natural biofilms that form on microplastics in lake water affect the adsorption of nine emerging organic contaminants. The study found that biofilm colonization on microplastic surfaces can significantly alter how these particles interact with pollutants, in some cases increasing and in others decreasing contaminant uptake compared to clean microplastics.
Environmental exposure more than plastic composition shapes marine microplastic‐associated bacterial communities in Pacific versus Caribbean field incubations
Researchers incubated six types of household plastic polymers in Pacific and Caribbean coastal waters to study the bacterial communities that form on microplastics. They found that geographic location and exposure time were far more important than plastic type in shaping these microbial communities. The study identified a core plastisphere of 57 bacterial variants common across all conditions, suggesting environmental context plays a bigger role than plastic composition in microplastic colonization.
Wastewater-induced microplastic biofouling in freshwater: role of particle size and flow velocity
This study examined how wastewater discharge promotes biofouling — the colonization of microplastics by microorganisms — in freshwater environments, finding that particle size and wastewater-derived nutrients both influenced biofilm formation rates and community composition. Wastewater-exposed microplastics rapidly developed distinct microbial communities.
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.
Microplastic selects for convergent microbiomes from distinct riverine sources
Laboratory experiments showed that microplastic particles from different freshwater sources recruited very similar bacterial communities regardless of their original environment, suggesting that microplastics selectively favor specific bacterial taxa. This convergent microbiome formation on microplastics could facilitate the spread of particular bacteria — including potential pathogens — across diverse water systems.