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61,005 resultsShowing papers similar to Surface functional groups and biofilm formation on microplastics: Environmental implications
ClearPhysicochemical behavior and ecological risk of biofilm-mediated microplastics in aquatic environments
This review explores how biofilm formation on microplastics in water environments changes their physical and chemical behavior, potentially increasing their ecological risks. Researchers found that biofilm-coated microplastics more readily absorb pollutants and antibiotic resistance genes, and may disrupt gut microbiota in organisms that ingest them. The findings suggest that the biological aging of microplastics in nature makes them more dangerous than freshly produced particles.
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.
Biofilm on microplastics in aqueous environment: Physicochemical properties and environmental implications
This review examines how bacteria and other microorganisms form sticky films called biofilms on microplastic surfaces in water. These biofilms change how microplastics move through the environment and increase their ability to absorb pollutants like heavy metals, pesticides, and antibiotics. Biofilm-coated microplastics may also carry harmful bacteria, making them a greater potential health risk than clean microplastic particles.
Effect of weathering on environmental behavior of microplastics: Properties, sorption and potential risks
This review examines how environmental weathering changes the physical and chemical properties of microplastics, affecting their ability to absorb pollutants and their toxicity to organisms. Researchers found that weathered microplastics develop altered surface chemistry, increased surface area, and changed color, all of which influence how they interact with contaminants and are ingested by aquatic life. The study also evaluates the toxic potential of chemical byproducts released during the weathering process itself.
Microplastic surface biofilms: a review of structural assembly, influencing factors, and ecotoxicity
This review explores how microbial biofilms form on microplastic surfaces in natural environments, creating tiny ecosystems known as the plastisphere. Researchers found that these biofilms change the physical and chemical properties of microplastics and can significantly alter their toxicity to living organisms. The study emphasizes that most toxicity research still uses pristine microplastics, which may not accurately reflect the real-world risks posed by biofilm-coated particles.
The Importance of Biofilms to the Fate and Effects of Microplastics
This review examines how biofilms — communities of microorganisms that form on microplastic surfaces — affect the fate and ecological effects of plastic pollution. Biofilm formation alters how microplastics are transported, ingested, and degraded in the environment, and the plastisphere can harbor pathogens and antibiotic-resistant bacteria that may pose risks to human health.
Microplastics in the environment: Interactions with microbes and chemical contaminants
This review covers what is known about microplastic interactions with microbes and co-occurring chemical contaminants in the environment, examining how biofilms on microplastics alter pollutant transport and the ecological consequences for soil, water, and atmospheric systems.
From Pristine to Laboratory-weathered Micro- and Nanoplastics: Interaction with Environmental Contaminants and Biological Effects
This review contrasts pristine and laboratory-weathered micro- and nanoplastics in terms of surface chemistry, adsorption of co-contaminants, and biological effects, arguing that weathered particles better represent real-world exposures and often exhibit different or greater toxicity.
A review on enriched microplastics in environment: From the perspective of their aging impact and associate risk
This review explores what happens to microplastics as they age in the environment over long periods. Researchers found that natural weathering changes the physical and chemical properties of microplastics in ways that may increase their ability to harbor harmful microorganisms and interact with other pollutants, suggesting that aging may actually make microplastic pollution more hazardous over time rather than less.
Environmental behaviors of microplastics in aquatic systems: A systematic review on degradation, adsorption, toxicity and biofilm under aging conditions
Aging processes like UV irradiation and physical abrasion alter microplastic surface properties, increasing their capacity to adsorb environmental pollutants while also enhancing leaching of toxic additives like phthalates, collectively amplifying the environmental toxicity of weathered microplastics.
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.
Rapid Physicochemical Changes in Microplastic Induced by Biofilm Formation
Researchers studied how biofilm formation rapidly changes the physical and chemical properties of microplastics over a two-week period. The study found significant two-way interactions between microbial communities and plastic surfaces, with biofilm colonization altering surface properties of polyethylene, polypropylene, and polystyrene, while the type of polymer influenced which microbial communities developed.
Impacts of Biofilm Formation on the Fate and Potential Effects of Microplastic in the Aquatic Environment
Researchers reviewed how biofilm formation on microplastic surfaces affects the fate and potential ecological effects of microplastics in aquatic environments, finding that biofilms alter particle buoyancy, surface chemistry, and interactions with organisms.
Effects of Weathering on Microplastic Dispersibility and Pollutant Uptake Capacity
This study examined how environmental weathering changes the surface properties of microplastics and their ability to absorb co-pollutants, finding that weathered MPs bind more contaminants than pristine particles due to surface oxidation and cracking. The results emphasize that the environmental fate and toxicity of microplastics change dynamically as they age in the environment.
Mechanism and characterization of microplastic aging process: A review
This review explains how microplastics age and break down in the environment through sunlight, heat, and chemical reactions, and why this aging process matters. As microplastics weather, their surfaces change in ways that make them better at absorbing toxic pollutants and more harmful to living organisms. Understanding these aging processes is important because the microplastics people encounter in food and water have typically been weathered, meaning they may be more dangerous than the fresh plastics used in most lab studies.
Insights into the Photoaging Behavior of Microplastics: Environmental Fate and Ecological Risk
This review examines how sunlight ages microplastics in the environment, breaking them into smaller pieces and changing their surface chemistry in ways that make them more toxic and more likely to carry other pollutants. Sun-aged microplastics release dissolved organic matter that can harm aquatic life, and their roughened surfaces attract more bacteria and chemical contaminants. Since most microplastics in nature have been exposed to sunlight, their real-world health risks may be higher than studies using fresh lab plastics suggest.
Surface functional groups determine adsorption of pharmaceuticals and personal care products on polypropylene microplastics
Researchers found that surface functional groups on aged polypropylene microplastics determined their adsorption capacity for pharmaceuticals and personal care products, with aged plastic showing much higher pollutant uptake than fresh plastic due to weathering-induced surface changes.
Aging Process of Microplastics in the Environment
This review examines how natural environmental processes — UV radiation, physical abrasion, chemical reactions, and biodegradation — alter the surface, shape, and chemistry of microplastics over time, and how these changes affect their ability to absorb and transport other pollutants. Understanding microplastic aging is critical because weathered particles behave differently than fresh plastic, often becoming more hazardous as pollutant carriers in ecosystems.
Change in adsorption behavior of aquatic humic substances on microplastic through biotic and abiotic aging processes
Researchers found that both UV irradiation and microbial aging of polyethylene microplastics significantly altered their surface chemistry, changing how aquatic humic substances adsorb onto the plastic surface and highlighting the importance of weathering state in assessing microplastic-contaminant interactions.
The wheel of time: The environmental dance of aged micro- and nanoplastics and their biological resonance
This review examines how micro- and nanoplastics change as they age in the environment through exposure to sunlight, water, and biological activity. Aged plastics behave differently than fresh ones: they accumulate faster in ecosystems, are more easily taken up by organisms, and can release trapped chemicals as they break down. The findings suggest that the real-world health and environmental risks of microplastics may be greater than lab studies using new, unweathered plastics indicate.
Microplastic-Associated Biofilms and Their Role in the Fate of Microplastics in Aquatic Environment
This review examines how microbial biofilms attached to microplastics in aquatic environments mediate the accumulation and transfer of chemical pollutants, exploring how the 'plastisphere' community influences the fate and ecotoxicological impact of microplastics and co-contaminants.
Biofilm-Developed Microplastics As Vectors of Pollutants in Aquatic Environments
This review examines how biofilms that form on microplastics in aquatic environments change their ability to absorb and transport pollutants. Researchers found that biofilm-coated microplastics can absorb more contaminants than clean microplastics and serve as vectors that transfer both pollutants and potentially harmful microorganisms through aquatic ecosystems.
Multi-mechanistic adsorption of pharmaceuticals and personal care products on oxidized microplastics: Oxidation processes, mechanisms, and environmental implications
Researchers reviewed how weathering and oxidation change microplastic surfaces, making them better at absorbing pharmaceuticals and personal care product chemicals from water. The modified surfaces attract these contaminants through multiple chemical forces, meaning aged microplastics in the environment act as enhanced carriers for drug and cosmetic pollutants.
Incubation habitats and aging treatments affect the formation of biofilms on polypropylene microplastics
Researchers studied how aging treatments and different aquatic habitats (marine, estuary, and river) affect biofilm formation on polypropylene microplastics. The study found that aging processes damaged the surface structure of microplastics and increased oxygen-containing groups, which enhanced microbial colonization. The results suggest that both environmental conditions and plastic degradation status significantly influence the microbial communities that form on microplastic surfaces.