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20 resultsShowing papers similar to Influence of microplastics on nutrients and metal concentrations in river sediments
ClearMicroplastics meet micropollutants in a central european river stream: Adsorption of pollutants to microplastics under environmentally relevant conditions
Researchers investigated how microplastics adsorb organic micropollutants in a Central European river under real-world conditions. They found that aged microplastics showed higher adsorption capacity for contaminants compared to pristine ones, and that the type of plastic material influenced which pollutants were absorbed. The findings suggest that microplastics in rivers can act as carriers for harmful chemicals, potentially spreading contamination through aquatic ecosystems.
Microplastics in river water: occurrence, weathering, and adsorption behaviour
Researchers examined microplastics in river water, characterizing their occurrence, degree of weathering, and capacity to adsorb co-contaminants. The study highlights microplastics as vectors that can transport and re-release other pollutants in freshwater systems.
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 is an Abundant and Distinct Microbial Habitat in an Urban River
Researchers demonstrated that microplastic surfaces in an urban river host a microbial community that is distinct from surrounding water and sediment communities, establishing microplastic as an abundant and ecologically distinct habitat for river microorganisms.
Evaluating the role of microplastics as a vector in metal cycling within the River Thames
Researchers characterized how microplastics in River Thames water adsorb toxic heavy metals, comparing adsorption capacity across different plastic types and water chemistry conditions. Microplastics consistently adsorbed metals including lead, cadmium, and copper, providing the first data on metal-binding capacity for Thames microplastics and supporting their role as carriers of inorganic pollutants in urban rivers.
The role of biofilm and hydrodynamics on the fate of microplastic particles in rivers: an experimental study
Researchers conducted experimental flume studies to investigate how biofilm formation and hydrodynamic conditions jointly govern microplastic particle fate in rivers, examining why some urbanized and industrialized river reaches show no significant upstream-to-downstream increase in microplastic concentration despite theoretical inputs.
New insights into the distribution and interaction mechanism of microplastics with humic acid in river sediments
Researchers found that microplastics and humic acids interact significantly in river sediments, with humic acid coating altering microplastic surface properties and affecting their distribution at different sediment depths, influencing the environmental fate and pollutant-carrying capacity of microplastics.
Adsorption of trace metals by microplastic pellets in fresh water
Researchers measured the adsorption of trace metals by microplastic pellets in freshwater, finding that pellets accumulate metals from the surrounding water, potentially concentrating metals and altering their bioavailability to aquatic organisms.
Interaction and bacterial effects of microplastics pollution on heavy metals in hyporheic sediments of different land-use types in the Beiluo River Basin
Researchers studied how microplastics and heavy metals interact in river sediments across different land-use types in a Chinese river basin. They found that microplastics concentrated more heavily in shallow sediments and that the metals detected on microplastic surfaces were present at much higher levels than in surrounding sediment. The study suggests that microplastics may serve as concentrators and carriers of heavy metal contamination, potentially amplifying pollution risks.
New insight into ammonium removal in riverbanks under the exposure of microplastics
Researchers discovered that microplastic accumulation in riverbank sediments decreases ammonium removal capacity by 8-13%, caused by reduced abundance of nitrifying bacteria, revealing a previously unknown mechanism by which plastic pollution impairs natural water purification.
Exaggerated interaction of biofilm-developed microplastics and contaminants in aquatic environments
Researchers found that biofilm formation on microplastic surfaces exaggerates the adsorption and vector capacity for co-contaminants in aquatic environments, with biofilm-coated MPs showing substantially higher uptake of contaminants than pristine MPs.
Abundance, Distribution and Drivers of Microplastic Contaminant in Urban River Environments
Researchers surveyed microplastic distribution in urban river environments and identified key drivers of accumulation hotspots, finding that land use, hydrology, and infrastructure factors concentrated microplastics at predictable locations that could inform targeted management interventions.
Association between microplastics and biofilm: a new perspective for monitoring microplastics in urban rivers
Researchers reviewed the use of biofilms as a monitoring matrix for microplastics in urban rivers, drawing on literature about microplastic occurrence in Brazilian rivers and biofilm-associated adsorption of emerging contaminants in freshwater. The study argues that biofilm analysis offers a complementary perspective to water and sediment monitoring because biofilms accumulate pollutants over days, providing an integrated signal of microplastic exposure in the water column.
Microplastics as an emerging anthropogenic vector of trace metals in freshwater: Significance of biofilms and comparison with natural substrates
Scientists placed virgin polystyrene microplastics in a eutrophic urban lake and a drinking water reservoir for four weeks to allow biofilm development, then measured trace metal accumulation, finding that biofilm-coated microplastics accumulated significantly more metals than virgin plastics or natural substrates.
Microplastics and trace metals in river sediment: Prevalence and correlation with multiple factors
Researchers examined microplastic and trace metal levels in river sediment in Vietnam and found that while metals tended to cluster together and correlate with nutrients and fine soil particles, they showed only weak connections to microplastic levels. The study suggests that microplastics and metals behave independently in river systems, each influenced by a different set of environmental factors.
Distribution and variation of metals in urban river sediments in response to microplastics presence, catchment characteristics and sediment properties
Researchers found that microplastic presence, alongside catchment urbanization and traffic activity, is associated with elevated heavy metal concentrations — particularly lead — in Brisbane River sediments, suggesting microplastics act as co-contaminants and vectors for metal pollution in urban waterways.
Mud and organic content are strongly correlated with microplastic contamination in a meandering riverbed
Researchers found that microplastic concentration in river sediments is strongly correlated with mud and organic content, with riverbank areas showing concentrations about ten times higher than the main channel. The study suggests that sediment composition and river flow dynamics play a key role in where microplastics accumulate within riverbeds.
Lead levels and abundance of microplastics in surface water and sediment along a rural–urban river gradient
Researchers sampled water and sediment along a rural-to-urban river and found microplastics at every location, with concentrations decreasing downstream in surface water but not following a clear pattern in sediment. They also found that higher microplastic levels in sediment were linked to higher lead concentrations, suggesting the two pollutants tend to accumulate together.
Effect of microplastics on the environmental behavior of emerging contaminants in aquatic matrices
This study examines how microplastics affect the environmental behavior of emerging contaminants in aquatic systems. Microplastics can adsorb other pollutants and alter their bioavailability, potentially increasing or decreasing toxic effects depending on the chemicals and environmental conditions.
The role of biofilm and hydrodynamics on the fate of microplastic particles in rivers: an experimental study
Researchers conducted flume and field experiments to examine how biofilm formation and hydrodynamic conditions govern the fate of microplastic particles in rivers, investigating why some MP-polluted rivers crossing industrialized areas show no significant upstream-to-downstream concentration differences. The study identified biofilm-mediated density changes and turbulence as key factors controlling whether low-density MPs remain suspended or settle into sediments.