We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
Papers
61,005 resultsShowing papers similar to Impacts of low concentrations of nanoplastics on leaf litter decomposition and food quality for detritivores in streams
ClearNanoplastic pollution inhibits stream leaf decomposition through modulating microbial metabolic activity and fungal community structure
Researchers found that polystyrene nanoplastics significantly inhibited leaf litter decomposition in freshwater streams, even at low concentrations. The study suggests this occurs through suppression of key microbial enzymes and shifts in fungal community structure, indicating that nanoplastic pollution could disrupt important nutrient cycling processes in freshwater ecosystems.
Response of a simulated aquatic fungal community to nanoplastics exposure and functional consequence on leaf decomposition
Researchers exposed a simulated stream fungal community to nano-polystyrene and found that even low concentrations (1–100 µg/L) suppressed fungal reproduction and reduced the abundance of Geotrichum candidum, slowing leaf litter decomposition by up to 27.9% and disrupting a key aquatic nutrient cycling function.
Polystyrene nanoparticles intensify the algae-mediated negative priming effect on leaf litter decomposition
Researchers showed that polystyrene nanoplastics intensify the natural inhibitory effect of benthic algae on leaf litter decomposition in streams, reducing decomposition rates by 21%, by depleting labile carbon transfer from algae to fungal decomposers and reducing fungal diversity, including key decomposer genera essential for aquatic nutrient cycling.
Effects of microsized and nanosized polystyrene on detrital processing and nutrient dynamics in streams
Researchers exposed a stream detrital food chain — leaf-decomposing microbes and a river snail — to nano- and microsized polystyrene particles and found that nanosized particles suppressed microbial growth while boosting certain enzymes, whereas microsized particles reduced leaf nitrogen content and snail feeding, indicating distinct ecological disruption pathways depending on particle size.
Evidence of micro and macroplastic toxicity along a stream detrital food-chain.
Both micro- and macroplastic polyethylene pieces inhibited the decomposition of leaf litter in freshwater streams, with microplastics reducing the feeding activity of stream invertebrates. Since leaf litter decomposition is a critical process that nutrients and energy flow into freshwater food webs, plastic pollution could disrupt these fundamental ecosystem functions.
Effects of nanoplastic exposure routes on leaf decomposition in streams
Researchers conducted a microcosm experiment showing that dietary exposure to nanoplastics — through eating contaminated leaf litter — more severely disrupts stream food webs than waterborne exposure, reducing microbial enzyme activity, lowering leaf lipid content, and decreasing river snail feeding rates by up to 17%.
Microplastics and silver nanoparticles compromise detrital food chains in streams through effects on microbial decomposers and invertebrate detritivores
Researchers tested how microplastics and silver nanoparticles, both common pollutants from personal care products, affect stream food webs built around decomposing leaf litter. They found that both pollutants, alone and in combination, reduced fungal decomposition and harmed invertebrate feeding and growth, disrupting the base of the food chain. The study suggests that the co-occurrence of these contaminants in freshwater could impair nutrient cycling in stream ecosystems.
Microplastics have lethal and sublethal effects on stream invertebrates and affect stream ecosystem functioning
Using a mesocosm experiment, researchers showed that microplastics at environmentally relevant concentrations caused lethal and sublethal effects on freshwater invertebrates and reduced key ecosystem functions including leaf litter decomposition and algal colonization of streambed substrates.
Nanoplastics intensify metal-induced impacts in freshwater ecosystems
Researchers found that polystyrene nanoplastics — both bare and carboxylated — intensified metal-induced impairment of leaf litter decomposition by aquatic hyphomycetes in freshwater microcosms, with combined stressor effects observed at environmentally relevant concentrations and amplified at higher exposures.
Microplastics and leaf litter decomposition dynamics: New insights from a lotic ecosystem (Northeastern Italy)
Researchers studied how microplastics affect the natural decomposition of plant litter in a freshwater stream over four seasons, finding that microplastics had a small but measurable negative effect on decomposition rates and accumulated inside the invertebrates responsible for breaking down organic matter. These findings suggest microplastic pollution subtly disrupts the nutrient cycling processes that keep freshwater ecosystems healthy.
Microplastics alter the leaf litter breakdown rates and the decomposer community in subtropical lentic microhabitats
Researchers exposed leaf litter decomposition systems to microplastics and measured breakdown rates and decomposer community composition, finding that microplastics slowed litter breakdown and shifted the abundance of invertebrate shredders and microbial decomposers. The study suggests microplastics could disrupt nutrient cycling in freshwater ecosystems by impairing a foundational ecological process.
Do microbial decomposers find micro- and nanoplastics to be harmful stressors in the aquatic environment? A systematic review of in vitro toxicological research
Researchers systematically reviewed in vitro studies on how bacteria and fungi respond to micro- and nanoplastics, finding that polystyrene particles and E. coli dominate the literature and that nanoplastic toxicity commonly disrupts antioxidative systems, gene expression, and cell membrane integrity in microbial decomposers.
Nanoplastic-mediated disruption of freshwater carbon cycling via modulating of plankton communities
Researchers exposed freshwater mesocosms to polystyrene nanoplastics (80–500 nm) at 1 mg/L and found significant disruption of zooplankton and bacterial community structure, which altered carbon cycling processes — suggesting nanoplastics can impair the ecosystem functions that regulate freshwater carbon flux.
Emerging Microplastics Alter the Influences of Soil Animals on the Fungal Community Structure in Determining the Litter Decomposition of a Deciduous Tree
Researchers investigated how microplastics in forest soil affect the interactions between soil animals and fungal communities during leaf litter decomposition. They found that the presence of microplastics altered fungal community structure and disrupted the beneficial influence that soil animals normally have on decomposition processes. The study suggests that microplastic contamination in forest ecosystems could interfere with nutrient cycling by changing how decomposer communities function.
Exposure to polystyrene nanoplastics reduces bacterial and fungal biomass in microfabricated soil models
Researchers used micro-engineered soil models to study how polystyrene nanoplastics affect soil bacteria and fungi. They found that nanoplastic exposure reduced both bacterial and fungal biomass, with bacteria showing a linear dose-dependent decline and fungi being affected even at the lowest concentrations. The study suggests that nanoplastic pollution in soil may suppress the microbial communities essential for healthy soil function.
Important ecological processes are affected by the accumulation and trophic transfer of nanoplastics in a freshwater periphyton-grazer food chain
Researchers found that nanoplastics bioaccumulate and transfer trophically in a freshwater periphyton-grazer food chain, affecting fundamental ecological processes and highlighting significant gaps in our understanding of nanoplastic risks in freshwater ecosystems.
Does functionalised nanoplastics modulate the cellular and physiological responses of aquatic fungi to metals?
Researchers investigated how functionalized nanoplastics interact with copper to affect aquatic fungi that play important roles as decomposers in freshwater ecosystems. The study found that polystyrene nanoplastics at environmentally realistic concentrations can modulate the cellular and physiological responses of the fungus Articulospora tetracladia to copper exposure.
Microplastic effects in aquatic ecosystems with special reference to fungi–zooplankton interaction: identification of knowledge gaps and prioritization of research needs
This review identifies a largely unexplored gap in microplastic research: how plastic pollution affects aquatic fungi and their interactions with zooplankton. Because fungi play critical roles in breaking down dead organic matter and serving as food for zooplankton, disruptions caused by microplastics — which can physically resemble fungal spores in size — could have cascading effects on freshwater food webs and nutrient cycling. The authors call for targeted experiments to fill this knowledge gap and better predict ecosystem-level impacts of microplastic contamination.
Microplastics in freshwater sediments: Effects on benthic invertebrate communities and ecosystem functioning assessed in artificial streams
Researchers tested the effects of polyethylene microplastics on freshwater invertebrate communities in artificial streams using environmentally relevant concentrations. They found that microplastics significantly reduced the abundance of deposit-feeding and grazing organisms by 31-50%, with chironomids and mayflies showing the highest ingestion of plastic particles.
Microplastics in freshwaters: Comparing effects of particle properties and an invertebrate consumer on microbial communities and ecosystem functions
Researchers tested how different microplastic properties, including concentration, shape, and polymer type, affect microbial communities and ecosystem functions in freshwater environments. They found that the presence of an invertebrate consumer had a stronger influence on microbial activity than the microplastics themselves, though high concentrations of certain particle shapes did alter community composition. The study suggests that the ecological effects of microplastics in freshwater depend heavily on the broader biological context.
Dual Effect of Microplastics and Cadmium on Stream Litter Decomposition and Invertebrate Feeding Behavior
Microcosm experiments showed that combined exposure to microplastics and cadmium reduced leaf litter decomposition rates and altered fungal communities and invertebrate feeding behavior in freshwater streams more than either stressor alone.
Can microplastics from personal care products affect stream microbial decomposers in the presence of silver nanoparticles?
This study exposed freshwater fungal decomposers to microplastics from personal care products and silver nanoparticles, individually and in combination, finding that both pollutants reduced microbial activity and that combined exposure often produced additive or synergistic inhibition. The results highlight the risk to stream-based decomposition processes from personal care product-derived pollutants.
Size-dependent impacts from polystyrene micro- and nanoplastics on freshwater invertebrates: A mesocosm study combining environmental DNA metabarcoding and morphological identification
A 14-week outdoor mesocosm experiment exposed natural freshwater invertebrate communities to 15 µm and 150 nm polystyrene particles, finding size-dependent effects on community composition with nanoplastics causing greater disruption than microplastics at environmentally relevant concentrations.
How do the Growth and Metabolic Activity of Aquatic fungi Geotrichum Candidum and Aspergillus Niger Respond to Nanoplastics?
This study exposed two aquatic fungal species, Geotrichum candidum and Aspergillus niger, to polystyrene and amine-modified polystyrene nanoparticles at environmental concentrations. Hormesis effects were observed at low PS concentrations for G. candidum growth, while A. niger was more sensitive, and both species showed altered enzyme activities involved in organic matter decomposition.