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 Assessment of the Effects of Biodegradable and NonbiodegradableMicroplastics Combined with Pesticides on the Soil Microbiota
ClearAssessment of the Effects of Biodegradable and Nonbiodegradable Microplastics Combined with Pesticides on the Soil Microbiota
This study compared how biodegradable PLA and conventional PET microplastics, combined with common pesticides, affect soil microbial communities. Researchers found that PLA microplastics significantly increased microbial diversity but also enriched potentially harmful bacteria and elevated antibiotic resistance gene abundance more than PET, suggesting biodegradable plastics may pose underappreciated ecological risks in agricultural soils.
The combination of microplastics and glyphosate affects the microbiome of soil inhabitant Enchytraeus crypticus
Researchers tested how microplastics and the common herbicide glyphosate affect soil health when present together. Biodegradable PLA plastic combined with glyphosate had the most damaging effects on both soil bacteria and the gut microbiome of soil worms, worse than conventional PET plastic. These results suggest that using biodegradable plastics alongside pesticides in agriculture may pose greater ecological risks than previously thought.
Potential environmental risks of field bio/non-degradable microplastic from mulching residues in farmland: Evidence from metagenomic analysis of plastisphere
Researchers analyzed the microbes living on biodegradable and conventional plastic mulch fragments in farm soil and found that both types harbored antibiotic resistance genes and disease-causing bacteria, including human pathogens. Surprisingly, the biodegradable plastic (PBAT/PLA) had a higher diversity and abundance of resistance genes than conventional polyethylene. This challenges the assumption that biodegradable plastics are always safer and raises concerns about antibiotic resistance spreading from farm microplastics.
Biodegradable microplastics exacerbate the risk of antibiotic resistance genes pollution in agricultural soils
This study found that biodegradable plastics (PLA and PBAT), often promoted as eco-friendly alternatives, actually increased antibiotic resistance genes in agricultural soil more than conventional plastics like polyethylene. The biodegradable plastics promoted the growth of bacteria that carry resistance genes and enhanced the ability of these genes to spread between organisms. These findings challenge the assumption that switching to biodegradable plastics will reduce environmental and health risks in farming.
Co-existence of polyethylene microplastics and tetracycline on soil microbial community and ARGs
This study examined how polyethylene microplastics and the antibiotic tetracycline interact in soil. When present together, they altered soil microbial communities and increased the abundance of antibiotic resistance genes more than either contaminant alone. The findings raise concerns that microplastics in agricultural soil may worsen the spread of antibiotic resistance, a growing public health challenge.
Dynamic impact of polyethylene terephthalate nanoplastics on antibiotic resistance and microplastics degradation genes in the rhizosphere of Oryza sativa L.
This study found that PET nanoplastics in rice paddy soil boosted the spread of antibiotic resistance genes in soil bacteria by up to significant levels. The plastics provided surfaces for bacteria to grow on and produced toxic byproducts that sped up gene sharing between microbes. This means microplastic pollution in agricultural soil could make antibiotic-resistant infections harder to treat in people.
Interactions of traditional and biodegradable microplastics with neonicotinoid pesticides
Researchers investigated how both traditional and biodegradable microplastics interact with neonicotinoid pesticides in agricultural environments. They found that all microplastic types could adsorb the pesticide thiacloprid, but biodegradable microplastics showed different sorption behavior and higher desorption rates compared to conventional plastics. The study suggests that biodegradable microplastics may actually increase pesticide mobility in soils, creating a previously unrecognized pathway for agricultural chemical contamination.
The impact of microplastic and sulfanilamide co-exposure on soil microbiota
This study investigated what happens when microplastics and the antibiotic sulfanilamide are present together in soil, finding that the combination significantly altered soil microbial communities compared to either pollutant alone. Both conventional polyethylene and biodegradable polylactic acid microplastics interacted with the antibiotic to change bacterial diversity and soil chemistry. The results show that microplastics and antibiotics in agricultural soil can have compounding effects on soil health, potentially affecting the crops grown in it.
Divergent impacts of conventional and biodegradable microplastics on pesticide fate and toxicity in a soil–chive system, underscoring a soil-plant-microbe disruption
Researchers found that biodegradable polylactic acid (PLA) microplastics, despite being marketed as eco-friendly, significantly delayed pesticide degradation in soil and increased plant uptake of a toxic pesticide metabolite by up to 59%. PLA disrupted beneficial soil bacteria and interfered with plant detoxification pathways, while conventional polyethylene microplastics had comparatively milder effects. The study suggests that biodegradable plastics may pose unexpected risks when they interact with pesticides in agricultural soils.
Effects of microplastic degradability and concentrations on antibiotic resistance genes between soil and phyllosphere
Researchers investigated how biodegradable polyglycolic acid and non-degradable high-density polyethylene microplastics at varying concentrations affected antibiotic resistance gene distribution and transfer between soil and phyllosphere in a greenhouse germination experiment. They found that biodegradable microplastics had a more pronounced effect on antibiotic resistance gene abundance in the phyllosphere, while soil antibiotic resistance genes were jointly regulated by both microplastic type and concentration.
Biodegradable microplastics show greater potential than conventional types in facilitating antibiotic resistance gene enrichment and transfer through viral communities
Researchers compared how conventional and biodegradable microplastics affect viral communities and antibiotic resistance genes in agricultural soils and found that biodegradable plastics posed a greater risk. Biodegradable microplastics significantly enriched high-risk antibiotic resistance genes and mobile genetic elements regardless of fertilizer type, while conventional microplastics had more limited effects. The study challenges the assumption that biodegradable plastics are inherently safer for soil ecosystems.
Influence of microplastic addition on glyphosate decay and soil microbial activities in Chinese loess soil
Adding polyethylene microplastics to soil influenced the degradation of the herbicide glyphosate and altered microbial activity, with effects depending on the concentration of both microplastics and glyphosate. The findings suggest that microplastic contamination in agricultural soils could affect how long pesticides persist and how soil microbes function.
Independent and combined effects of microplastics pollution and drought on soil bacterial community
Researchers studied how polyethylene and polylactic acid microplastics, combined with drought conditions, affect soil bacteria. Very small (20 micrometer) biodegradable PLA microplastics significantly reduced bacterial diversity by over 17%, while conventional polyethylene had less impact. The results suggest that the combined stress of microplastic pollution and drought could meaningfully alter soil microbial communities that are essential for healthy ecosystems and agriculture.
The effects of single and combined pollution of PE microplastics and antibiotics in soil on wheat (Triticum aestivum L.) seedlings
This study examined the combined effects of polyethylene microplastics and antibiotic exposure on soil organisms, finding that mixture exposure altered soil microbial community structure and promoted antibiotic resistance gene abundance more than either stressor alone. Co-exposure to microplastics and antibiotics poses compounded risks for soil microbiomes.
Different effects of bio/non-degradable microplastics on sewage sludge compost performance: Focusing on antibiotic resistance genes, virulence factors and key metabolic functions
Researchers compared how biodegradable and conventional microplastics affect antibiotic resistance genes and microbial communities during sewage sludge composting. They found that both types of microplastics increased the abundance of antibiotic resistance genes, but non-biodegradable polypropylene had a stronger effect on promoting harmful virulence factors. The study raises concerns that microplastic contamination in composted sludge could spread antibiotic resistance when applied to agricultural land.
Microplastics combined with tetracycline in soils facilitate the formation of antibiotic resistance in the Enchytraeus crypticus microbiome
Soil invertebrates (Enchytraeus crypticus) were exposed to microplastics and tetracycline alone and in combination; combined exposure promoted greater shifts in gut microbiome composition and higher levels of antibiotic resistance genes than either stressor alone, suggesting microplastics exacerbate antibiotic resistance spread in soil.
Biodegradable microplastics induced the dissemination of antibiotic resistance genes and virulence factors in soil: A metagenomic perspective
Researchers found that biodegradable microplastics promoted the spread of antibiotic resistance genes and virulence factors in soil at levels comparable to conventional microplastics, challenging assumptions about their environmental safety.
The combined effect of microplastics and tetracycline on soil microbial communities and ARGs
Researchers studied how simultaneous exposure to microplastics and tetracycline affects soil microbial communities, finding that the combination disrupted microbial diversity, altered functional gene expression, and promoted horizontal transfer of antibiotic resistance genes beyond the effects of either pollutant alone.
Effect of polyethylene microplastics on antibiotic resistance genes: A comparison based on different soil types and plant types
This study compared how polyethylene microplastics affect antibiotic resistance genes across different soil types and found that contaminated soils and the presence of certain plants influenced which resistance genes proliferated. The results suggest that microplastics in agricultural soil can help spread antibiotic resistance, which is a serious concern for human health because resistant bacteria can enter the food supply through crops.
Co-exposure of microplastics and sulfamethoxazole propagated antibiotic resistance genes in sediments by regulating the microbial carbon metabolism
This study found that when microplastics and the antibiotic sulfamethoxazole are present together in river sediments, certain types of microplastics amplify the spread of antibiotic resistance genes among bacteria. Biodegradable PLA plastic promoted more resistance gene spread than conventional polyethylene, likely by altering how bacteria metabolize carbon. This means microplastic pollution in waterways could be helping create antibiotic-resistant bacteria, posing an indirect but serious threat to human health.
DeterminingAntimicrobial Resistance in the Plastisphere:Lower Risks of Nonbiodegradable vs Higher Risks of Biodegradable Microplastics
Researchers determined the prevalence and diversity of antimicrobial resistance genes in the plastisphere (biofilm on microplastics) compared to surrounding water and sediment, finding that non-biodegradable plastics hosted distinct resistance gene profiles with lower overall resistance risk than biodegradable plastic surfaces.
Insight into combined pollution of antibiotics and microplastics in aquatic and soil environment: Environmental behavior, interaction mechanism and associated impact of resistant genes
This review examines the combined pollution created when microplastics absorb antibiotics in water and soil environments. Researchers found that microplastics can concentrate antibiotics on their surfaces, and this combination promotes the spread of antibiotic-resistant genes in microbial communities. The study highlights that the interaction between these two emerging pollutants may pose greater environmental and health risks than either one alone.
Sources, interactions, influencing factors and ecological risks of microplastics and antibiotic resistance genes in soil: A review
Microplastics in soil serve as hotspots for antibiotic resistance genes, with the plastisphere — the microbial community colonizing plastic surfaces — facilitating horizontal gene transfer of resistance markers. Key factors driving this interaction include microplastic properties, soil chemistry, and agricultural practices, though research in soil environments is still at an early stage compared to aquatic systems.
The plastisphere of biodegradable and conventional microplastics from residues exhibit distinct microbial structure, network and function in plastic-mulching farmland
Researchers compared the bacterial communities that colonize biodegradable and conventional plastic microplastics in farmland soil. They found that biodegradable plastics (PBAT/PLA) and conventional polyethylene each attracted distinct microbial communities with different functions, including bacteria that could degrade plastics or cycle nutrients. The results suggest that even biodegradable plastics create unique microbial environments in soil that may affect soil health and function in unexpected ways.