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61,005 resultsShowing papers similar to Impacts of nano- and micro-plastics exposure on zooplankton grazing, bacterial communities, and dimethylated sulfur compounds production in the microcosms
ClearEffects of micro- and nano-plastics on community assemblages and dimethylated sulfur compounds production
Researchers conducted a field microcosm experiment to study how micro- and nanoplastics affect marine plankton communities and the production of climate-relevant sulfur compounds. They found that medium and high concentrations of polystyrene, polyethylene, and polyamide particles disrupted zooplankton grazing and altered the production of dimethyl sulfide. The study suggests that plastic pollution could interfere with marine biogeochemical cycles that play a role in climate regulation.
Size-dependent influences of nano- and micro-plastics exposure on feeding, antioxidant systems, and organic sulfur compounds in ciliate Uronema marinum
Researchers studied how nano- and microplastics of different sizes affect a marine ciliate that plays a key role in ocean sulfur cycling. Exposure to polystyrene particles reduced the organisms' ability to feed on algae, which in turn dramatically decreased their production of dimethyl sulfide, a gas important for climate regulation. The findings suggest that plastic pollution could disrupt fundamental ocean chemistry processes beyond its direct effects on individual organisms.
Microplastics stress alters microorganism community structure and reduces the production of biogenic dimethylated sulfur compounds
This study examined how microplastic stress affects marine microbial community structure and the production of dimethylsulfoniopropionate (DMSP) and dimethyl sulfide (DMS) -- sulfur compounds that play key roles in global sulfur cycling and cloud formation. Microplastic exposure altered microbial community composition and significantly reduced DMSP and DMS production, indicating potential cascading effects on global climate-regulating biogeochemical cycles.
Effects of micro- and nano-plastics on growth, antioxidant system, DMS, and DMSP production in Emiliania huxleyi
Researchers exposed a key ocean-dwelling algae species to polystyrene micro- and nanoplastics and found that both sizes impaired growth and triggered oxidative stress. The nanoplastics were more harmful than microplastics, reducing chlorophyll content and altering the production of climate-relevant sulfur compounds. The study suggests that plastic pollution could disrupt ocean algae that play an important role in regulating atmospheric chemistry and climate.
Effects of microplastics exposure on ingestion, fecundity, development, and dimethylsulfide production in Tigriopus japonicus (Harpacticoida, copepod)
Researchers tested how polyethylene and nylon-6 microplastics affect the copepod Tigriopus japonicus, finding that microplastic exposure reduced feeding and reproductive output and suppressed the production of the climate-relevant gas dimethylsulfide during copepod grazing.
Microplastics Stress Alters Microorganism Community Structure and Reduces the Production of Biogenic Dimethylated Sulfur Compounds
Researchers studied how microplastic stress alters marine microbial community composition and affects production of dimethylsulfoniopropionate (DMSP) and dimethyl sulfide, which play key roles in global sulfur cycling and cloud formation. Microplastic exposure shifted microbial community structure and significantly reduced DMSP and DMS production, with potential implications for climate-relevant atmospheric sulfur emissions from the ocean.
Decreased Dimethylsulfideand Increased PolybrominatedMethanes: Potential Climate Effects of Microplastic Pollution in AcidifiedOcean
Researchers conducted a ship-based microcosm experiment examining the combined effects of microplastic pollution and ocean acidification on short-lived biogenic climate-active gases, finding that these stressors together decreased dimethylsulfide while increasing polybrominated methanes, suggesting novel climate feedback pathways.
Decreased Dimethylsulfideand Increased PolybrominatedMethanes: Potential Climate Effects of Microplastic Pollution in AcidifiedOcean
Researchers conducted a ship-based microcosm experiment to investigate how combined microplastic pollution and ocean acidification affect biogenic climate-active gases, finding decreased dimethylsulfide and increased polybrominated methanes, with potential implications for marine climate regulation.
Impacts of co-exposure to nanoplastics and ofloxacin on marine planktonic microbial communities and DMSP dynamics
Researchers conducted a 19-day experiment examining how nanoplastics and the antibiotic ofloxacin, alone and in combination, affect marine microbial communities and sulfur cycling in coastal seawater. Combined exposure produced significantly stronger negative effects than either pollutant alone, reducing microbial biomass, simplifying community networks, and disrupting the cycling of DMSP, a compound important for marine food webs and climate regulation.
Effects of nanoplastics exposure on ingestion, life history traits, and dimethyl sulfide production in rotifer Brachionus plicatilis
Researchers exposed tiny marine organisms called rotifers to polystyrene nanoplastics and found that the particles accumulated in their digestive tracts, shortened their lifespans, and reduced their ability to reproduce. Higher concentrations also decreased the production of dimethyl sulfide, a compound important for cloud formation and climate regulation. This study shows that nanoplastic pollution can affect marine organisms at the base of the food chain, with potential ripple effects on both ecosystems and the climate.
Decreased Dimethylsulfide and Increased Polybrominated Methanes: Potential Climate Effects of Microplastic Pollution in Acidified Ocean
A ship-based microcosm experiment simulating ocean acidification and microplastic pollution found that combined conditions decreased dimethylsulfide production and increased polybrominated methane emissions, with potential climate-active gas implications for ocean carbon cycling.
Size dependent effects of nanoplastics and microplastics on the nitrogen cycle of microbial flocs
Researchers found that nano- and microplastics reduce the nitrogen cycling capacity of microbial flocs used in aquaculture, with smaller nanoplastics causing greater disruption than larger microplastics in a size-dependent toxicity pattern.
Combined toxicity of nanoplastics and microcystin-LR to sulfate-reducing bacteria and the underlying mechanisms
Researchers exposed freshwater aquaculture microcosms to polyethylene nanoplastics and the algal toxin microcystin-LR, finding that nanoplastics strongly adsorb the toxin and that combined exposure disrupts sulfur cycling bacteria more severely than either contaminant alone, raising ecological concerns for aquaculture water quality.
Size-specific mediation of the physiological responses and degradation ability of microalgae to sulfamerazine by microplastics
Researchers examined how polystyrene microplastics of different sizes affect the ability of marine microalgae to tolerate and break down the antibiotic sulfamerazine. They found that nano-sized plastics were more harmful than larger particles, reducing algal growth and impairing the organisms' ability to degrade the antibiotic. The study reveals that microplastic pollution could interfere with the natural biological breakdown of pharmaceutical contaminants in waterways.
Heterotrophic Dinoflagellate Growth and Grazing Rates Reduced by Microplastic Ingestion
Researchers found that polystyrene microplastic ingestion significantly reduced the growth and grazing rates of heterotrophic dinoflagellates, suggesting that microplastic pollution could disrupt marine microbial food webs at the single-celled predator level.
Toxicity of nanoplastics to zooplankton is influenced by temperature, salinity, and natural particulate matter
Researchers found that increased temperature and salinity promoted nanoplastic toxicity to zooplankton, while the presence of organic matter and natural colloids mitigated toxic effects, suggesting environmental conditions significantly modulate nanoplastic risks.
Micro- and nanoplastics effects in a multiple stressed marine environment
Researchers examined how micro- and nanoplastics interact with other environmental stressors in marine settings, finding that realistic multi-stressor scenarios can amplify or modify plastic toxicity in ways single-exposure studies miss.
Warming and microplastic pollution shape the carbon and nitrogen cycles of algae
Researchers investigated how ocean warming combined with microplastic pollution affects carbon and nitrogen cycling in marine diatoms and dinoflagellates, revealing that these combined stressors alter key biochemical processes in dominant phytoplankton species.
Do microplastics affect marine ecosystem productivity?
This study estimated the potential impact of microplastics on marine ecosystem productivity (algae and zooplankton growth) by synthesizing lab toxicity data. The analysis suggested that current environmental microplastic concentrations may reduce primary productivity in some ocean regions, with knock-on effects up the food chain.
How do microplastics affect the marine microbial loop? Predation of microplastics by microzooplankton
This study examined how micro- and nanoplastics affect marine protozoans that serve as key links in the microbial loop, the process of material and energy cycling in ocean ecosystems. Results showed that both size classes of plastic particles impaired protozoan predation on bacteria, potentially disrupting carbon and nutrient transfer in marine microbial food webs.
Nanoplastics impact on marine biota: A review
Researchers reviewed the emerging toxicological literature on nanoplastics in marine ecosystems, distinguishing primary nanoplastics (manufactured at nanoscale) from secondary nanoplastics (fragmented from larger debris), and summarizing how nanoscale size changes particle reactivity and bioavailability in ways that differ substantially from their macro- and microscale counterparts.
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.
Microplastics Reshape the Fate of Aqueous Carbon by Inducing Dynamic Changes in Biodiversity and Chemodiversity
Researchers found that microplastics reshape aqueous carbon cycling by releasing chemical additives that inhibit autotrophic bacteria, promoting CO2 emissions, and stimulating microbial metabolic pathways that transform dissolved organic matter into more stable, less bioavailable forms.
Toxic effects on ciliates under nano-/micro-plastics coexist with silver nanoparticles
Researchers tested the combined effects of different-sized plastic particles with silver nanoparticles on marine microorganisms and found that the mixture was more toxic than either pollutant alone. Smaller nanoplastics combined with silver nanoparticles caused the most severe damage, disrupting energy and fat metabolism and causing DNA and protein damage. This study shows how microplastics can amplify the toxicity of other environmental pollutants in marine food chains.