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61,005 resultsShowing papers similar to ОСОБЕННОСТИ ПОВЕДЕНИЯ МИКРОПЛАТИКА В ВОДНОЙ СРЕДЕ: ПЛАСТИСФЕРА - НОВАЯ МОРСКАЯ ЭКОСИСТЕМА
ClearPlastisphere - a new habitat of microbial community: Composition, structure and ecological consequences
This review examines the plastisphere — microbial communities colonizing microplastics — covering the composition and structure of plastisphere microbiomes across marine, freshwater, and terrestrial environments and discussing ecological consequences including pathogen dispersal.
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.
Surfing and dining on the “plastisphere”: Microbial life on plastic marine debris
This review examines the microbial communities — the "plastisphere" — that colonize floating plastic debris in the ocean, discussing how these biofilms form, who lives in them, and what risks they may pose to marine ecosystems and human health. The unique chemistry and buoyancy of plastic creates a novel habitat that can transport potentially harmful microbes across ocean basins.
Microplastics in Aquatic Environments
This review summarizes the current state of microplastic research in aquatic environments, covering the plastisphere — the microbial community that colonizes plastic surfaces — and the ways microplastics interact with other aquatic organisms. The paper highlights microplastics as a growing ecological concern that affects food webs and ecosystem processes.
(micro)Plastic biofilms: Keeping afloat by carving out a new niche
This review examined how microplastics serve as persistent substrates for microbial biofilm formation in natural environments, creating a novel ecological niche called the plastisphere that hosts distinct microbial communities. The authors discussed how these biofilms alter microplastic surface properties and may enhance the persistence and transport of plastic particles and associated microbes.
Ecology of the plastisphere
This review explores the plastisphere, the diverse microbial community that colonizes plastic debris in the ocean, which now spans multiple biomes on Earth. Researchers examine how microplastics serve as novel substrates for microbial colonization and may facilitate the dispersal of microorganisms, including potentially harmful species, across aquatic ecosystems. The study highlights key questions about whether plastics harbor a unique core microbial community distinct from natural surfaces.
Exploring the Microbiome of the Marine Microplastisphere
This review examines the microbiome associated with microplastic particles in marine environments, known as the microplastisphere, describing it as a dynamic and complex ecosystem with significant ecological implications. Researchers found that the microplastisphere harbors distinct microbial communities distinct from surrounding seawater, with potential consequences for marine biodiversity and pollutant transport.
Microbial colonization and degradation of marine microplastics in the plastisphere: A review
This review explores the "plastisphere" — the community of microorganisms that colonize microplastics floating in the ocean. Researchers found that bacteria, fungi, algae, and other microbes form unique biofilm communities on plastic surfaces, some of which can partially degrade the plastic while others include potentially harmful pathogens. Understanding these microbial communities is important for assessing both the ecological risks and possible bioremediation potential of marine microplastic pollution.
Biofilm formation and its implications on the properties and fate of microplastics in aquatic environments: A review
Researchers reviewed how microplastics in water attract and support communities of bacteria and other microorganisms that form biofilms — living coatings that alter the plastic particles' movement, help them carry pathogens, and affect how toxic chemicals attached to the plastic are absorbed by living things. Understanding this "plastisphere" ecosystem is critical for predicting where microplastics go and how harmful they become.
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 Importance of Biofilms on Microplastic Particles in Their Sinking Behavior and the Transfer of Invasive Organisms between Ecosystems
This review explores how biofilm formation on microplastic surfaces, known as the plastisphere, affects the transport and ecological impact of plastic particles in marine environments. Researchers found that biofilm colonization can cause microplastics to sink from the ocean surface, altering their distribution through the water column, while also providing a habitat that protects invasive microbial species. The study suggests that some plastisphere organisms with plastic-degrading abilities could potentially be harnessed for marine pollution cleanup strategies.
Plastisphere community assemblage of aquatic environment: plastic-microbe interaction, role in degradation and characterization technologies
This review examines the plastisphere—microbial communities colonizing plastic surfaces in aquatic environments—covering how these biofilms form, their role in plastic biodegradation, and current characterization technologies for studying plastic-microbe interactions.
(micro)Plastic biofilms: Keeping afloat by carving out a new niche
This review examined how microplastics accumulate microbial biofilms, creating a distinct ecological niche with unique community composition and metabolic activities. The microplastic biofilm, or plastisphere, can harbor pathogens and antibiotic-resistant bacteria, raising concerns about plastic particles as vectors of biological hazards.
Environmental Health Impact of Plastisphere
This review examines the growing body of research on plastisphere ecosystems in aquatic environments including rivers, lakes, and estuaries, discussing microbial community composition on plastic surfaces and the ecological consequences for freshwater biodiversity and function.
Dynamics, ecological implications, and mitigation strategies of the ocean plastisphere
This review examines how plastic debris accumulates in marine environments, fragmenting into micro- and nanoplastics through physical, chemical, and biological processes. Researchers found that plastic surfaces serve as substrates for microbial colonization, forming complex biofilm communities known as the plastisphere, which can affect marine organisms through ingestion and trophic transfer. The study highlights the need for coordinated global strategies combining policy, technology, and public awareness to reduce marine plastic pollution.
Potential impact of marine-derived plastisphere as a Vibrio carrier on marine ecosystems: Current status and future perspectives
This review examines how microplastics in the ocean serve as floating platforms for Vibrio bacteria, which are significant pathogens threatening aquaculture and marine ecosystem health. Researchers found that the so-called plastisphere, the microbial community that colonizes plastic surfaces, can enhance the survival and spread of these harmful bacteria. The study highlights a concerning link between plastic pollution and the potential amplification of waterborne disease risks.
Plastisphere in freshwaters: An emerging concern
This review introduced the concept of the freshwater plastisphere - the microbial community colonizing plastic debris in rivers and lakes - and found that freshwater plastisphere communities are compositionally distinct from marine ones and from ambient water microbiomes, with implications for pathogen dispersal and plastic degradation in inland waters.
Marine Plastic Debris: A New Surface for Microbial Colonization
This review examines the "Plastisphere" -- the community of microbes that rapidly colonizes plastic debris in the ocean -- covering biofilm development, potential biodegradation, and the hitchhiking of harmful bacteria. Researchers found that microbial communities on plastics do not dramatically differ from those on other inert surfaces, especially in mature biofilms. The study identifies key knowledge gaps and calls for more environmentally realistic research into how these plastic-associated microbes interact with marine ecosystems.
Aquatic Microbial Diversity on Plastisphere: Colonization and Potential Role in Microplastic Biodegradation
This review examines how microorganisms colonize the surfaces of floating plastic debris in aquatic environments, forming communities known as the plastisphere. Researchers found that certain bacteria and fungi on plastic surfaces show potential for biodegrading the polymers they inhabit. The study suggests that understanding these microbial communities could lead to biological approaches for breaking down microplastic pollution in waterways.
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.
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.
Microplastic-Associated Biofilms: A Comparison of Freshwater and Marine Environments
This review compared microplastic-associated biofilm communities in freshwater and marine environments, examining how plastic type, ecosystem, and environmental conditions shape the microbial communities that colonize plastic surfaces. Understanding these "plastisphere" communities is important because they may include pathogens and can affect the fate and transport of plastic particles.
Freshwater plastisphere: a review on biodiversity, risks, and biodegradation potential with implications for the aquatic ecosystem health
This review examines the communities of microbes that colonize plastic debris in freshwater environments, known as the "plastisphere." These microbial communities include potentially dangerous bacteria and organisms that can carry antibiotic resistance genes, meaning plastic pollution may serve as a vehicle for spreading pathogens and drug-resistant infections through water systems that people rely on.
Responses of natural plastisphere community and zooplankton to microplastic pollution: a review on novel remediation strategies
This review examines how microbial communities colonize microplastic surfaces in aquatic environments, forming what scientists call the plastisphere, and how these plastic-associated microbes interact with zooplankton. Researchers found that microplastics serve as floating platforms for bacteria, including potentially harmful species, and can transfer these microbes up the food chain through zooplankton ingestion. The study highlights novel bioremediation strategies that harness natural microbial processes to help break down microplastic pollution.