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61,005 resultsShowing papers similar to Microbial Community Dynamics and Biogeochemical Cycling in Microplastic-Contaminated Sediment
ClearEffects of microplastics on nitrogen and phosphorus cycles and microbial communities in sediments
Researchers found that PVC, PLA, and polypropylene microplastics altered nitrogen and phosphorus cycling in freshwater sediments by shifting microbial community composition, with effects varying by polymer type and biodegradability.
Unveiling the impact of microplastics with distinct polymer types and concentrations on tidal sediment microbiome and nitrogen cycling
Researchers tested how five different types of microplastics at varying concentrations affect microbial communities and nitrogen cycling in tidal sediments over 30 days. They found that microplastics generally reduced microbial diversity and enhanced nitrogen fixation, with biodegradable PLA plastic showing concentration-dependent effects. The study suggests that microplastic contamination in coastal sediments can disrupt important nutrient cycling processes driven by microorganisms.
Microplastics affect organic nitrogen in sediment: The response of organic nitrogen mineralization to microbes and benthic animals
Researchers investigated how different types of microplastics affect organic nitrogen cycling in sediments, measuring the responses of key nitrogen-transforming microorganisms. They found microplastics alter the composition of organic nitrogen and suppress certain nitrogen cycling processes.
Polyethylene microplastics interfere with the nutrient cycle in water-plant-sediment systems
Researchers studied how polyethylene microplastics affect nutrient cycling in freshwater systems containing submerged plants and sediment. They found that the microplastics significantly reduced nitrogen and carbon content in plant leaves and disrupted the microbial communities in sediment responsible for nutrient processing. The study demonstrates that microplastic pollution can interfere with fundamental biogeochemical cycles that maintain the health of aquatic ecosystems.
Can Microplastic Pollution Change Important Aquatic Bacterial Communities?
Microplastics in coastal sediments can change the composition of important bacterial communities that cycle nutrients and maintain ecosystem health. Microplastic-associated bacteria differ significantly from natural sediment bacteria, with potential consequences for the chemical processes these communities perform.
Effects of microplastics on the structure and function of bacterial communities in sediments of a freshwater lake
Researchers examined how microplastics alter the structure and function of bacterial communities in sediments, finding that plastic exposure shifted community composition and reduced overall diversity compared to plastic-free controls. Functional analysis showed impaired denitrification and organic matter decomposition in microplastic-contaminated sediments, indicating ecosystem-level consequences for nutrient cycling.
Recent advances in impacts of microplastics on nitrogen cycling in the environment: A review
This review examined how microplastics affect nitrogen cycling, a critical process in soil, water, and sediment ecosystems driven by microbial communities. Researchers found that the type, size, and concentration of microplastics can alter microbial populations responsible for nitrogen transformation, disrupting processes like nitrification and denitrification. The study highlights that chemical additives released from microplastics may also play a role, though the underlying mechanisms are not yet fully understood.
Microbes drive metabolism, community diversity, and interactions in response to microplastic-induced nutrient imbalance
Researchers investigated how conventional and biodegradable microplastics alter soil nutrient balances and the resulting effects on microbial metabolism, community diversity, and species interactions. The study found that microplastic-induced nutrient imbalances significantly influenced soil microbial processes, with different types of microplastics producing distinct effects on carbon and nitrogen cycling.
Microplastics alter the microbiota-mediated phosphorus profiles at sediment-water interface: Distinct microbial effects between sediment and plastisphere
This study found that microplastics in lake sediments change how bacteria process phosphorus, a key nutrient in freshwater ecosystems. Both petroleum-based and biodegradable microplastics altered bacterial communities and phosphorus cycling, but in different ways depending on whether bacteria were in the sediment or on the plastic surfaces. These changes could contribute to water quality problems like algal blooms that affect both ecosystems and the drinking water supply.
Microplastics affect sedimentary microbial communities and nitrogen cycling
A microcosm experiment showed that microplastics added to salt marsh sediment altered microbial community composition and disrupted nitrogen cycling, including reduced denitrification rates, suggesting that microplastic contamination could impair important biogeochemical functions.
Discrepancy strategies of sediment abundant and rare microbial communities in response to floating microplastic disturbances: Study using a microcosmic experiment
Using microcosm experiments with fluvial sediment exposed to four plastic types, researchers found that floating microplastics altered sediment microbial diversity and reduced bacteria involved in carbon and nitrogen cycling. Abundant microbial taxa were more sensitive to microplastic disturbance than rare taxa, and microplastics decreased network complexity and increased negative species interactions in microbial communities.
A Study of the Effects of Microplastics on Microbial Communities in Marine Sediments
This study investigated how the presence of microplastics in marine sediments affects microbial communities and, specifically, the methane cycle, finding that microplastics significantly altered microbial community structure and function. Since marine sediment microbes play a critical role in regulating greenhouse gas emissions, microplastic contamination could have broader climate-relevant effects beyond direct toxicity.
Hotspots lurking underwater: Insights into the contamination characteristics, environmental fates and impacts on biogeochemical cycling of microplastics in freshwater sediments
This review examines how microplastics accumulate in freshwater lake and river sediments, which act as major collection points for these particles. Researchers found that microplastic distribution in sediments varies significantly depending on local conditions, and that the particles can alter nutrient cycling and affect sediment-dwelling organisms. The study highlights freshwater sediments as critical but understudied hotspots for microplastic contamination.
Biodegradability of microplastics reshapes surface biofilm microbial community structure and nitrogen cycling functions in aquatic environments
Researchers compared how biodegradable (PLA) and non-biodegradable (polyethylene and PVC) microplastics affect the microbial communities that form on their surfaces in aquatic environments, finding substantial differences in which bacteria colonized each plastic type and how they processed nitrogen. PLA supported communities rich in nitrogen-cycling bacteria, while PVC and polyethylene enriched different microbial groups associated with pollutant degradation. The study suggests that the push toward biodegradable plastics will change — not just reduce — the ecological effects of microplastics in rivers and lakes.
Microplastics impair extracellular enzymatic activities and organic matter cycling in oligotrophic sandy marine sediments
Researchers investigated how microplastic contamination affects the breakdown of organic matter in sandy marine sediments. They found that microplastics significantly reduced the activity of key enzymes responsible for decomposing organic material, disrupting normal nutrient cycling processes. The study suggests that microplastic accumulation on the seafloor could impair the ecosystem services provided by benthic sediment communities.
Microplastics and soil microbiomes
This review examines the two-way relationship between microplastics and soil microbiomes: how microplastics alter microbial community structure and function, and how soil microbes in turn affect the behavior of microplastics. Researchers found that microplastics can shift microbial communities and disrupt key ecosystem processes like nutrient cycling. The study also discusses how certain soil microbes may enhance the degradation of microplastics, pointing to potential natural remediation pathways.
Effects of microplastics on soil microorganisms and microbial functions in nutrients and carbon cycling – A review
This review examines how microplastics in soil alter the communities of bacteria and fungi that are essential for recycling nutrients like nitrogen, phosphorus, and carbon. Microplastics can increase certain beneficial bacteria but decrease others that are important for soil fertility, and they also carry toxic chemicals that further disrupt microbial life. The authors note that most studies are short-term lab experiments, and long-term field studies are needed to understand real-world impacts.
Regulatory path for soil microbial communities depends on the type and dose of microplastics
Researchers compared how six types of microplastics at different concentrations affect soil microbial communities, testing both conventional and biodegradable plastics. They found that biodegradable microplastics had a greater impact on soil carbon and nitrogen levels than conventional ones, and that the type and dose of microplastic determined which microbial groups were most affected. The findings suggest that even so-called biodegradable plastics can significantly alter soil ecosystems when they break down into microplastic-sized particles.
Microplastic induces microbial nitrogen limitation further alters microbial nitrogentransformation: Insights from metagenomic analysis
Researchers studied how both conventional and biodegradable microplastics affect nitrogen cycling in soil over 120 days. They found that biodegradable microplastics significantly disrupted microbial nitrogen processes by acting as a carbon source that shifted bacterial communities toward nitrogen-fixing species. The findings suggest that even biodegradable plastics in soil can alter nutrient availability in ways that may affect soil fertility and plant growth.
Impact of Microplastic on Freshwater Sediment Biogeochemistry and Microbial Communities Is Polymer Specific
Researchers used a microcosm approach to test how three common plastic types found in Great Lakes sediments affect freshwater benthic biogeochemistry and microbial communities. They found that each polymer had distinct effects: PET fibers decreased ecosystem metabolism, PVC particles increased nutrient uptake, and tire-derived rubber most substantially altered microbial community function. The study highlights that the environmental impact of microplastics in freshwater sediments depends heavily on the specific polymer type involved.
Microplastics alter microbial structure and assembly processes in different soil types: Driving effects of environmental factors
Researchers investigated how biodegradable polylactic acid and conventional polyethylene microplastics affect soil microbial communities across different soil types. They found that PLA increased dissolved organic carbon and pH while decreasing nitrogen availability, whereas polyethylene had contrasting effects depending on soil type. The study reveals that microplastic impacts on microbial community structure and assembly processes are soil-type-specific, with dissolved organic carbon driving changes in red soil and pH being the primary factor in fluvo-aquic soil.
Effects of microplastics on microbial community dynamics in sediments from the Volturno River ecosystem, Italy
Researchers investigated microplastic pollution in the Volturno River in southern Italy, examining how microplastics affect microbial communities in river sediments. The study found that microplastic presence altered microbial community composition and diversity, suggesting that plastic pollution may disrupt important ecological processes in freshwater sediment environments.
Microplastic impacts on soil and sediment bioturbation: insights from microcosm experiments across diverse ecosystems
This study used microcosm experiments across terrestrial, freshwater, and marine ecosystems to assess whether microplastics affect bioturbation — the physical reworking of sediment and soil by organisms. Microplastic exposure reduced bioturbation activity in multiple ecosystems, with implications for nutrient cycling and sediment health.
Is soft-sediments ecosystem service delivery compromised due to microplastic pollution?
This review examines how microplastic pollution may compromise ecosystem service delivery in soft-sediment habitats, focusing on potential impacts on microphytobenthic microbial communities that underpin nutrient cycling, sediment stabilization, and food web productivity. The authors argue that because soft sediments act as microplastic sinks, their resident microbial communities face disproportionate exposure, and call for holistic research linking microplastic effects on microbial diversity and biogeochemical function to broader ecosystem service outcomes.