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61,005 resultsShowing papers similar to Bacterial pathogen assemblages on microplastic biofilms in coastal waters
ClearUnique Bacterial Community of the Biofilm on Microplastics in Coastal Water
Researchers compared bacterial communities forming biofilms on steel, silica, and PVC microplastic surfaces in coastal seawater and found that biofilm composition differed by material type. This shows that the type of plastic surface influences which microbial communities colonize it, with implications for how microplastics may spread specific bacteria.
Exploring changes in microplastic-associated bacterial communities with time, location, and polymer type in Liusha Bay, China
Researchers tracked how bacterial communities colonizing different types of microplastics changed over time in an aquaculture bay in China. They found that both exposure duration and plastic type significantly influenced which bacteria grew on the surfaces, with hydrocarbon-degrading species becoming notably abundant. Concerning from a health perspective, the pathogenic bacterium Vibrio was detected on all microplastic samples, suggesting that floating plastics may serve as rafts for disease-causing organisms.
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.
Harmful algae and pathogens on plastics in three mediterranean coastal lagoons
Researchers studied microplastics and macroplastic debris in three French Mediterranean coastal lagoons and found high-diversity biofilm communities including harmful algae and bacterial pathogens colonizing plastic surfaces, demonstrating that plastics can act as vectors for harmful microorganisms in sensitive coastal ecosystems.
[Enrichment Characteristics and Ecological Risk Prediction of Pathogens on Typical Microplastic Biofilms].
This study investigated which pathogens preferentially colonize biofilms on different types of microplastic surfaces in aquatic environments and assessed the associated ecological and public health risks. Microplastic biofilms showed selective enrichment of specific pathogen groups compared to surrounding water, with biofilm-forming potential varying by polymer type.
Bacterial colonisation dynamics of household plastics in a coastal environment
This study tracked how quickly and what kinds of bacteria colonized common household plastics (including bottles, bags, and packaging) placed in a coastal estuary environment. Bacteria colonized all plastic types within days, and the communities that formed included potential human pathogens. Plastic-associated bacterial communities in coastal environments could pose public health risks through seafood contamination or contact with polluted water.
Profiles of bacterial assemblages from microplastics of tropical coastal environments
Microplastic pieces collected from tropical coastal environments in Malaysia were found to host distinct bacterial communities that differed from surrounding seawater, including potential pathogens and plastic-degrading bacteria. The study contributes to understanding the plastisphere in tropical regions, where warm temperatures may accelerate both microbial colonization and plastic degradation.
Plastics and Microplastics as Vectors for Bacteria and Human Pathogens
This study reviewed how marine plastic debris serves as a surface for bacterial colonization, including human pathogens, and examined the novel communities forming on plastic surfaces. The research raises public health concerns about microplastics acting as rafts that transport harmful bacteria to new locations, including to seafood and coastal recreational areas.
Investigating the composition and distribution of microplastics surface biofilms in coral areas
Researchers investigated the composition and distribution of microbial biofilms on microplastic surfaces collected from coral reef areas. The study found that microplastics harbor distinct microbial communities including potentially pathogenic species, raising concerns that microplastic pollution may contribute to coral disease by serving as vectors for harmful microorganisms in reef ecosystems.
Dynamics and implications of biofilm formation and community succession on floating marine plastic debris
Researchers examined how biofilms form on plastic debris in aquatic environments and how the resulting microbial communities evolve over time, finding that the plastisphere hosts distinct microbial assemblages including potential pathogens. The study has implications for understanding plastic debris as a vector for microbial dispersal.
The composition of bacterial communities associated with plastic biofilms differs between different polymers and stages of biofilm succession
Researchers tracked bacterial community development on five different plastic types submerged in coastal waters over two months. They found that bacterial community composition varied by both plastic type and stage of colonization, with distinct early and late succession patterns. The study provides evidence that different plastics may host different microbial communities, which has implications for understanding how plastic pollution influences marine microbial ecology.
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.
Time-series incubations in a coastal environment illuminates the importance of early colonizers and the complexity of bacterial biofilm dynamics on marine plastics
Researchers used time-series incubations in a coastal marine environment to track plastisphere biofilm formation on microplastics, finding that early bacterial colonizers play a disproportionate role in shaping community dynamics and that biofilm composition is highly complex, varying with polymer type, incubation time, and surrounding environment.
Formation of specific bacterial assemblages on sterile polyethylene microplastic particles added to a marine aquaria system
Researchers characterized bacterial assemblages that formed on sterile polyethylene microplastic particles after 12 weeks of incubation in marine aquaria, comparing the plastisphere communities to those on sterile sandy sediment and in water fractions to determine whether microplastics select for distinct or potentially pathogenic bacterial communities. The study found that microplastics hosted specific bacterial assemblages distinct from surrounding environmental fractions, confirming their role as selective surfaces for microbial colonization.
Role of Microplastics as Attachment Media for the Growth of Microorganisms
Researchers reviewed how microplastics serve as attachment media for microbial growth, finding that biofilms forming on microplastic surfaces create unique microbial communities — including potential pathogens — that differ from those in surrounding environments.
Dynamics and functions of microbial communities in the plastisphere in temperate coastal environments
Researchers explored microbial communities colonizing microplastics in coastal environments of Japan, comparing bacterial and fungal communities across different plastic types, water, sediment, and sand. The study found that while microbial communities varied by sample type and location rather than plastic shape, microplastics harbored hydrocarbon-degrading organisms as well as potential pathogens, highlighting the ecological significance of plastic-associated biofilms.
Microbial Communities on Plastic Polymers in the Mediterranean Sea
Researchers collected floating microplastics from a bay in the Mediterranean and analyzed their bacterial biofilm communities using 16S rRNA sequencing, finding that microbial communities on plastics were distinct from surrounding seawater and differed between polymer types.
Alteration of microbial mediated carbon cycle and antibiotic resistance genes during plastisphere formation in coastal area
Researchers investigated how microplastic surfaces in coastal environments develop biofilm communities, known as the plastisphere, and whether these biofilms enrich antibiotic resistance genes. The study found that incubation time, habitat type, and microplastic aging state all significantly influenced biofilm composition, and that aged microplastics accumulated more antibiotic resistance genes than new ones, suggesting microplastics may serve as vectors for spreading resistant bacteria.
Characterization of Microplastic-Associated Biofilm Development along a Freshwater-Estuarine Gradient
Researchers characterized biofilm bacterial communities on three types of microplastics incubated along a freshwater-estuarine gradient, finding that salinity and plastic type influenced microbial community composition and succession over a 31-day period.
Dynamic evolution of microbial colonization on indoor microplastics: polymer diversity-driven co-occurrence networks and health risks
Researchers simulated 90 days of indoor microplastic exposure to study how different polymer types, aging, and morphology influence microbial colonization on microplastic surfaces. They found that polymer diversity shaped microbial co-occurrence networks and that the resulting plastisphere communities harbored potential human pathogens.
Bacterial community succession and the enrichment of antibiotic resistance genes on microplastics in an oyster farm
Researchers placed different types of microplastics in an oyster farm for 30 days and found that the plastics quickly became coated with bacteria, including antibiotic-resistant strains and potential human pathogens. The bacterial communities on plastic surfaces were distinct from those in the surrounding water and varied by plastic type. This means microplastics in seafood farming areas could serve as vehicles for spreading dangerous bacteria to humans through the food chain.
Potentially pathogenic bacteria in the plastisphere from water, sediments, and commercial fish in a tropical coastal lagoon: An assessment and management proposal
Researchers examined the types of potentially harmful bacteria living on microplastics found in water, sediments, and commercial fish in a tropical coastal lagoon. They identified several pathogenic species colonizing the microplastic surfaces, which could pose risks when contaminated fish are consumed by humans. The study proposes management strategies to reduce the public health threat of microplastic-associated pathogens in fisheries.
Evaluation of prokaryotic and eukaryotic microbial communities on microplastic‐associated biofilms in marine and freshwater environments
Researchers analyzed microbial biofilm communities on microplastic surfaces in both marine and freshwater environments, finding that plastic-associated biofilms harbor distinct prokaryotic and eukaryotic communities with potential roles in plastic biodegradation.
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.