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20 resultsShowing papers similar to Wastewater treatment alters microbial colonization of microplastics released to the environment
ClearWastewater treatment alters microbial colonization of microplastics
Analysis of microplastics and their biofilms across raw sewage, effluent, and sludge at two wastewater treatment plants found that >99% of influent MPs were retained in sludge, and that wastewater treatment substantially altered biofilm microbial composition, enriching bioflocculation-associated taxa.
Tracking the Evolution of Microbial Communities on Microplastics through a Wastewater Treatment Process: Insight into the “Plastisphere”
Researchers tracked how bacterial communities form and evolve on polystyrene microplastics as they pass through primary, secondary, and tertiary stages of wastewater treatment. They found that biofilms on the microplastics harbored greater bacterial diversity than surrounding water, with certain pioneer species facilitating further microbial colonization. The study reveals that bacteria attached to microplastics become more resistant to treatment processes than free-floating bacteria, raising concerns about microplastics as carriers of potentially harmful microbes in treated effluent.
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.
Selective microbial attachment to LDPE plastic beads during passage through the wastewater network
Researchers tracked how microbial communities colonize plastic beads as they travel through different stages of a wastewater treatment plant. They found that distinct bacterial communities selectively attached to the plastic surfaces at each treatment stage, differing from the microbes in the surrounding water. The study reveals that microplastics passing through wastewater systems accumulate unique microbial hitchhikers that could carry pathogens or antibiotic-resistant bacteria into the environment.
Determinants of microbial colonization on microplastics through wastewater treatment processes: The role of polymer type and sequential treatment
This study examined how polymer type (HDPE vs. PET) and sequential versus individual deployment at each wastewater treatment stage affect microbial colonization on microplastics. The stage of wastewater treatment was found to profoundly influence the bacterial communities colonizing microplastic surfaces.
Microbial Succession on Microplastics in Wastewater Treatment Plants: Exploring the Complexities of Microplastic-Microbiome Interactions
This review examines how different microorganisms colonize microplastic surfaces in wastewater treatment plants, forming communities called biofilms that change as the treatment process progresses. These biofilms can include harmful bacteria and antibiotic-resistant organisms that ride on microplastics through the treatment process and into the environment. The findings are concerning because microplastics leaving treatment plants could carry disease-causing microbes into waterways used for drinking and recreation.
The factors affecting bacterial colonisation on microplastics and the impact of tertiary treatment of wastewater on the attached bacteria and microplastics
This study examined the factors that influence bacterial colonization on microplastics and tested how tertiary wastewater treatment affects the bacteria and microplastics discharged from a treatment plant. Microplastic-associated biofilms in wastewater can carry harmful and antibiotic-resistant bacteria into receiving water bodies.
Investigating the roles of microbes in biodegrading or colonizing microplastic surfaces
Researchers investigated the roles of microbes in biodegrading or colonizing microplastic surfaces, examining how microbial communities interact with plastic polymers in environmental settings. The study characterized the 'plastisphere' — the community of microorganisms that colonize microplastic surfaces — and assessed the extent to which microbial activity contributes to plastic degradation in natural environments.
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.
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.
The dangerous transporters: A study of microplastic-associated bacteria passing through municipal wastewater treatment
This study characterized bacterial communities attached to microplastics sampled from multiple stages of a municipal wastewater treatment plant, finding that diverse bacteria including potential pathogens and antibiotic-resistant strains remained attached to microplastics through all treatment steps. The results suggest microplastics could transport hazardous bacteria through wastewater treatment and into receiving environments.
Marine Microbial Assemblages on Microplastics: Diversity, Adaptation, and Role in Degradation
This review examines microbial communities that colonize microplastics in the ocean, collectively known as the plastisphere. Researchers found that these biofilms differ significantly from those on natural surfaces and may include pathogenic bacteria and species capable of partially degrading plastics. The study highlights both the ecological risks of microplastics as vectors for harmful microbes and the potential for harnessing plastic-degrading organisms.
Identification of microplastic-associated microbial communities from various stages of wastewater treatment and recipient surface waters using MALDI-TOF mass spectrometry
Researchers deployed six polymer types at different stages of wastewater treatment across three Hungarian plants and used MALDI-TOF mass spectrometry to identify the bacteria colonizing microplastic surfaces, finding distinct microbial communities that may act as vectors for antibiotic resistance.
The plastisphere ecology: Assessing the impact of different pollution sources on microbial community composition, function and assembly in aquatic ecosystems
Researchers studied the microbial communities living on microplastic surfaces (called the plastisphere) across four different aquatic sites and found that plastics host a distinctly different mix of microbes than the surrounding water, shaped by local pollution sources. These plastic-surface microbes also carry more antibiotic resistance genes and show greater potential for breaking down plastics, making the plastisphere both a health concern and a potential bioremediation resource.
Microbial colonization of microplastic particles in aquatic systems
This review examined how microplastic particles become colonized by diverse microbial communities in aquatic environments, forming the so-called plastisphere. The research highlights that microplastics create novel ecological niches and may facilitate the spread of pathogens and antibiotic resistance genes in freshwater and marine systems.
Antibiotic resistance genes and virulence factors in the plastisphere in wastewater treatment plant effluent: Health risk quantification and driving mechanism interpretation
Researchers found that microplastics in treated wastewater carry significantly more disease-causing bacteria, antibiotic resistance genes, and virulence factors on their surfaces compared to the surrounding water. This means microplastics released from wastewater treatment plants into rivers and lakes could spread antibiotic-resistant infections, posing a direct risk to communities that rely on these water sources.
Year-Long Microbial Succession on Microplastics in Wastewater: Chaotic Dynamics Outweigh Preferential Growth
Researchers conducted a year-long study of microbial succession on microplastics in a wastewater treatment plant, finding that chaotic community dynamics outweigh any preferential colonization by plastic-specific microorganisms, challenging the concept of a consistent plastisphere microbiome.
Unveiling the plastisphere in anammox process: Physicochemical evolution of microplastics and microbial succession dynamics
Researchers tracked how polyethylene terephthalate microplastics change physically and chemically over 30 days in an anaerobic wastewater treatment system. They found that while the microplastics had minimal impact on nitrogen removal efficiency, they developed distinct microbial communities on their surfaces that evolved over time. The study provides new insights into how microplastics interact with beneficial microbes in wastewater treatment processes.
Wastewater discharges and polymer type modulate the riverine plastisphere and set the role of microplastics as vectors of pathogens and antibiotic resistance
Researchers investigated how wastewater treatment plant discharges and polymer type shape microbial communities on microplastics in a river environment. They found that microplastics harbored significantly higher microbial diversity than surrounding water, and that wastewater discharges led to a 2.3-fold increase in antibiotic resistance gene abundance on the plastic surfaces. Different polymer types, including polyethylene, polypropylene, and PET, each attracted distinct microbial communities with varying levels of pathogens and resistance genes.
Taxonomic variation, plastic degradation, and antibiotic resistance traits of plastisphere communities in the maturation pond of a wastewater treatment plant
Researchers placed different types of weathered plastics in a wastewater treatment pond for up to a year and studied the microbial communities that grew on them. The study suggests that the bacteria colonizing plastics in wastewater were shaped more by time and water depth than by the type of plastic, and that these communities may carry genes related to plastic degradation and antibiotic resistance.