We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
Papers
20 resultsShowing papers similar to Toxic effects on ciliates under nano-/micro-plastics coexist with silver nanoparticles
ClearMicro-/nano-plastics as vectors of heavy metals and stress response of ciliates using transcriptomic and metabolomic analyses
This study examined how polystyrene microplastics and nanoplastics interact with cadmium to affect single-celled marine organisms called ciliates. The combined exposure was more toxic than either pollutant alone, disrupting the organisms' metabolism and stress responses at the genetic level. The findings demonstrate that microplastics can make heavy metal pollution worse by carrying metals into cells, a concern for marine food web contamination that could ultimately affect seafood safety.
Size-dependent toxicity of nano- and microplastics with zinc oxide nanoparticles in the marine rotifer Brachionus koreanus
Researchers studied the combined toxic effects of zinc oxide nanoparticles with nano- and microplastics on marine rotifers. They found that the presence of plastic particles increased the toxicity of zinc oxide, with nanoplastics causing more harm than microplastics, and the combined exposure reduced reproduction and population growth. The study demonstrates that microplastics can amplify the harmful effects of other environmental contaminants on small marine organisms.
Co-exposure effects of polystyrene nanoplastics and silver nanoparticles in constructed wetlands: Microbial and macrophyte responses
Researchers co-exposed constructed wetlands to polystyrene nanoplastics and silver nanoparticles and found synergistic disruption of the electron transport chain, impaired ATP production, and altered nitrogen transformation, with combined exposure more toxic than either contaminant alone.
Insights into the interaction of microplastic with silver nanoparticles in natural surface water
Researchers co-exposed three common microplastics — polypropylene, polyethylene, and polystyrene — with silver nanoparticles in natural freshwater and brackish water, finding that their interaction altered the environmental behavior and fate of both contaminants. The results suggest that combined pollution from microplastics and nanomaterials produces effects distinct from either pollutant alone.
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.
Neurobehavioral toxicity induced by combined exposure of micro/nanoplastics and triphenyltin in marine medaka (Oryzias melastigma)
When marine medaka fish were exposed to both nanoplastics and the toxic chemical triphenyltin together, they showed much worse nerve and behavioral damage than from either pollutant alone. The combined exposure significantly reduced the fish's swimming ability and disrupted neural gene expression, with smaller nanoplastics causing more severe effects than larger microplastics. This highlights that real-world conditions, where microplastics coexist with other pollutants, may produce amplified toxic effects on the nervous system.
The combined effects of phenanthrene and micro-/nanoplastics mixtures on the cellular stress responses of the thick-shell mussel Mytilus coruscus
Scientists exposed thick-shell mussels to a combination of micro- and nanoplastics along with a common pollutant (phenanthrene) to study their combined effects. The mixtures caused more severe immune cell damage, increased oxidative stress, and stronger inflammatory responses than either pollutant alone. Evidence indicates that micro- and nanoplastics can worsen the toxic effects of organic pollutants in marine shellfish.
Ecotoxicity of emerging pollutants: Interactive impact of polystyrene nanoplastics and Metanil yellow on Artemia salina
Researchers exposed a common marine test animal, brine shrimp, to polystyrene nanoplastics combined with a synthetic yellow dye and found the mixture was far more toxic than either substance alone, killing over 93% of shrimp. The dye coated the nanoplastic surfaces, increased particle size, and amplified oxidative stress, showing that nanoplastics can make co-existing pollutants more dangerous.
Individual and Combined Toxic Effects of Nano-ZnO and Polyethylene Microplastics on Mosquito Fish (Gambusia holbrooki)
Researchers studied the individual and combined effects of polyethylene microplastics and zinc oxide nanoparticles on mosquito fish. The combination caused greater damage to liver tissue, blood parameters, and antioxidant systems than either pollutant alone. The findings suggest that microplastics interacting with other environmental contaminants can amplify toxic effects in aquatic organisms.
Molecular mechanism for combined toxicity of micro(nano)plastics and carbon nanofibers to freshwater microalgae Chlorella pyrenoidosa
Researchers tested how microplastics, nanoplastics, and carbon nanofibers affect freshwater algae individually and in combination, finding that the combined effects were significantly worse than either pollutant alone. Nanoplastics combined with carbon nanofibers caused the most severe cellular stress, damaging cell membranes, increasing oxidative stress, and disrupting energy metabolism. Since algae form the base of aquatic food chains, this damage could cascade through ecosystems and affect the safety of water and seafood for humans.
Microplastic Fibers Increase Sublethal Effects of AgNP and AgNO3 in Daphnia magna by Changing Cellular Energy Allocation
PET microplastic fibers combined with silver nanoparticles or silver nitrate increased sublethal toxicity in Daphnia magna compared to each stressor alone, with combined exposure altering cellular energy allocation and suggesting synergistic effects.
Combined toxic effects of nanoplastics and norfloxacin on mussel: Leveraging biochemical parameters and gut microbiota
Researchers exposed mussels to nanoplastics and the antibiotic norfloxacin, both alone and together, and found that the combination caused greater biochemical stress than either pollutant alone. Nanoplastics appeared to carry the antibiotic into mussel tissues, increasing its bioavailability and impact on gut microbiota. The findings suggest that nanoplastics can amplify the toxicity of other contaminants in marine organisms.
Particulate matter and nanoplastics: synergistic impact on Artemia salina
Combining nanoplastics with particulate matter (airborne or aquatic fine particles) produces worse outcomes for the brine shrimp Artemia salina than either pollutant alone, reducing survival and vitality. This synergistic toxicity is important because in real environments, nanoplastics rarely exist in isolation — they co-occur with other pollutants, making risk assessments based on single-contaminant studies likely to underestimate harm.
Synergistic effects of marine pollutants and microplastics on the destabilization of lipid bilayers
Researchers found that marine pollutants and microplastics act synergistically to destabilize lipid bilayers, suggesting that the combined presence of plastic particles and co-adsorbed chemicals may amplify cellular membrane damage beyond what either stressor causes alone.
Environmental behavior and toxic effects of micro(nano)plastics and engineered nanoparticles on marine organisms under ocean acidification: A review.
This review examined how ocean acidification interacts with the toxicity of micro- and nano-plastics and engineered nanoparticles in marine ecosystems, finding that lower pH can alter particle surface chemistry and enhance toxic effects in some organisms. The combined stressor perspective is important because climate change and plastic pollution are co-occurring in the same marine environments.
Microplastics at an environmentally relevant dose enhance mercury toxicity in a marine copepod under multigenerational exposure: Multi-omics perspective
Researchers exposed tiny marine organisms called copepods to microplastics and mercury together across three generations at levels found in the environment. While microplastics alone had little effect, they made mercury much more toxic by increasing how much mercury built up in the organisms' bodies. This study shows that microplastics can act as carriers that amplify the harmful effects of other environmental pollutants, with the damage worsening over generations.
Insights into the synergistic toxicity mechanisms caused by nano- and microplastics with triclosan using a dose-dependent functional genomics approach in Saccharomyces cerevisiae
Researchers used yeast functional genomics to investigate the combined toxicity of polystyrene nano- and microplastics with the antimicrobial compound triclosan. They found that the combined exposure produced synergistic toxic effects that were more harmful than either contaminant alone, disrupting cellular processes related to membrane integrity and protein function. The study provides molecular-level evidence that microplastics may amplify the toxicity of co-occurring chemical pollutants.
Interactive toxicity effects of metronidazole, diclofenac, ibuprofen, and differently functionalized nanoplastics on marine algae Chlorella sp.
Researchers examined the combined toxicity of common pharmaceutical drugs and nanoplastics with different surface coatings on marine algae. They found that the interaction between drugs and nanoplastics produced effects ranging from additive to synergistic, depending on the specific combination, with amine-coated nanoplastics generally causing more harm. The study highlights that real-world mixtures of pharmaceutical and plastic pollutants in oceans may pose greater risks to marine life than either contaminant alone.
Microplastic potentiates triclosan toxicity to the marine copepodAcartia tonsa(Dana)
Researchers tested whether microplastics worsen the toxicity of triclosan — an antimicrobial chemical — on marine copepods, finding that microplastic potentiated triclosan's toxic effects, suggesting that microplastics can increase the harm of co-occurring chemical contaminants.
Combined toxic effects of environmental predominant microplastics and ZnO nanoparticles in freshwater snail Pomaceae paludosa
Researchers assessed the toxic effects of zinc oxide nanoparticles and polypropylene microplastics, both individually and combined, on the freshwater snail Pomeacea paludosa over 28 days. The study found that combined exposure caused more severe oxidative stress, disrupted antioxidant and digestive enzyme activity, and led to tissue damage and DNA damage compared to individual pollutant exposure. Evidence indicates that microplastics interacting with nanoparticles can amplify toxic effects in freshwater organisms.