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61,005 resultsShowing papers similar to Sodium hypochlorite residual in the environment facilitated the spread of antibiotic resistance genes: through microplastics as a medium
ClearContribution of microplastic particles to the spread of resistances and pathogenic bacteria in treated wastewaters
Researchers studied microplastic particles collected from treated wastewater effluents and found that MPs harbored significantly higher loads of antibiotic resistance genes and pathogenic bacteria compared to surrounding water, suggesting MPs facilitate their environmental spread.
Enhanced propagation of intracellular and extracellular antibiotic resistance genes in municipal wastewater by microplastics
Researchers investigated how microplastics in municipal wastewater can carry and promote the spread of antibiotic resistance genes, including those found both inside and outside bacterial cells. They found that microplastics adsorbed both types of resistance genes and enhanced their transfer between bacteria through horizontal gene transfer. The study reveals that microplastics in wastewater systems may act as an underappreciated accelerator of antibiotic resistance spread.
Unraveling the effect of micro/nanoplastics on the occurrence and horizontal transfer of environmental antibiotic resistance genes: Advances, mechanisms and future prospects
This review examines how micro- and nanoplastics promote the spread of antibiotic resistance genes in the environment. The tiny plastic particles create conditions that help bacteria exchange resistance genes more easily by generating oxidative stress, making cell membranes more permeable, and providing surfaces where resistant bacteria can form communities. This is a growing public health concern because antibiotic-resistant infections are increasingly difficult to treat.
Microplastics can selectively enrich intracellular and extracellular antibiotic resistant genes and shape different microbial communities in aquatic systems
Researchers examined how microplastics of different types selectively capture antibiotic resistance genes and shape microbial communities in aquatic systems. They found that microplastics enriched both intracellular and extracellular antibiotic resistance genes, with the enrichment patterns varying by plastic type. The study suggests that microplastics may serve as hotspots for the spread of antimicrobial resistance in wastewater and natural water environments.
Selectively enrichment of antibiotics and ARGs by microplastics in river, estuary and marine waters
Researchers investigated how microplastics interact with antibiotics and antibiotic resistance genes across river, estuary, and marine environments of varying salinity. They found that microplastics can concentrate both antibiotics and antibiotic resistance genes from surrounding water, with this enrichment effect being strongest in freshwater and decreasing as salinity increases. The study raises concerns that microplastics may serve as vehicles for spreading antibiotic resistance in aquatic ecosystems.
From Interface to Cell: The Complex Interaction and Transfer Process Coupling Mechanism between Microplastics and Antibiotic Resistance Genes
Researchers examined how microplastic surfaces act as vectors for spreading antibiotic resistance genes in wastewater treatment systems. The study found that aged microplastics of PET, PE, and PP promoted bacterial adhesion, enhanced horizontal gene transfer, and triggered overproduction of reactive oxygen species, ultimately amplifying the spread of antimicrobial resistance through multiple molecular mechanisms.
Microplastics as hubs enriching antibiotic-resistant bacteria and pathogens in municipal activated sludge
Researchers demonstrated that microplastics in municipal wastewater treatment plants act as "hubs," selectively concentrating antibiotic-resistant bacteria and pathogens in their surface biofilms, with antibiotic-resistance genes enriched up to 4.5-fold compared to sand particles — raising concerns about microplastics spreading drug-resistant microbes into the environment.
Microplastics exhibit accumulation and horizontal transfer of antibiotic resistance genes
Researchers investigated whether microplastics in wastewater treatment plants can accumulate and spread antibiotic resistance genes. They found that bacteria growing on microplastic surfaces in treatment tanks harbored antibiotic resistance genes and transferred them at higher rates than bacteria in the surrounding water. This suggests microplastics in wastewater systems may serve as hotspots for spreading antibiotic resistance, posing potential risks to both ecosystems and human health.
A review on the effect of micro- and nano-plastics pollution on the emergence of antimicrobial resistance
This review highlights how microplastics serve as breeding grounds for antimicrobial resistance genes, examining the overlooked interaction between plastic pollution and antibiotic resistance that poses combined threats to environmental and human health.
Microplastic-Mediated Dissemination of Antibiotic Resistance Genes in Marine Environments: Mechanisms, Environmental Modulators, and Emerging Risks
This review examines how microplastics serve as vectors for spreading antibiotic resistance genes in marine environments through biofilm formation and horizontal gene transfer. Researchers found that plastic surfaces promote colonization by resistant bacteria, and environmental factors like salinity, UV exposure, and co-occurring heavy metals further accelerate the spread of resistance genes, posing significant ecological and public health risks.
Impacts of disinfectant and antipyretic on aged ethylene-vinyl acetate copolymer microplastics in hospital wastewater: Resistance genes, microbial community and carbon source metabolism
Researchers examined how two common hospital chemicals — a disinfectant (benzethonium chloride) and a painkiller (acetaminophen) — affect the microplastic particles made of ethylene-vinyl acetate that end up in hospital wastewater. Aged EVA microplastics exposed to these chemicals became better carriers for antibiotic resistance genes and promoted more microbial colonization than fresh plastics, raising concerns about hospitals as sources of resistance gene spread through microplastics. This highlights a under-studied pathway by which microplastics in healthcare settings could contribute to the global antibiotic resistance crisis.
(Nano)microplastics promote the propagation of antibiotic resistance genes in landfill leachate
Researchers found that (nano)microplastics in municipal landfill leachate actively promote the spread of antibiotic resistance genes, highlighting landfill sites as dual reservoirs of plastic pollution and antimicrobial resistance threats.
Microplastics pollution in the ocean: Potential carrier of resistant bacteria and resistance genes
This review examined microplastics in marine environments as carriers of antibiotic-resistant bacteria and resistance genes, finding that plastic surfaces selectively enrich resistance genes through horizontal gene transfer and co-selection pressure, making ocean microplastics a vector for resistance dissemination across ecosystems.
Fates of extracellular and intracellular antibiotic resistance genes in activated sludge and plastisphere under sulfadiazine pressure
Researchers found that microplastics in wastewater treatment systems act as reservoirs for antibiotic resistance genes, with the plastic surfaces (plastisphere) harboring more resistance genes than the surrounding sludge. When exposed to the antibiotic sulfadiazine, the spread of resistance genes on microplastic surfaces increased, and DNA from potential pathogens was detected. This suggests that microplastics leaving wastewater treatment plants could carry drug-resistant bacteria into waterways, posing a risk to public health.
Microplastics shape microbial interactions and affect the dissemination of antibiotic resistance genes in different full-scale wastewater treatment plants
A study of three full-scale wastewater treatment plants found that microplastics were associated with increased spread of antibiotic resistance genes (ARGs), with microplastic surfaces appearing to facilitate microbial interactions that promote ARG transfer. This is a significant public health concern because wastewater plants that fail to fully remove microplastics may also be inadvertently accelerating the dissemination of antibiotic resistance into receiving waterways.
Effects of polyvinyl chloride microplastics and benzylalkyldimethylethyl compounds on system performance, microbial community and resistance genes in sulfur autotrophic denitrification system
Researchers found that PVC microplastics and a common disinfectant chemical in wastewater treatment systems promoted the spread of antibiotic resistance genes, with the disinfectant having an even stronger effect than the microplastics. The microplastic surfaces harbored disease-causing bacteria that carried these resistance genes. This is concerning because wastewater treatment plants could be releasing both microplastics and antibiotic-resistant pathogens into waterways, potentially threatening human health.
Responses of bacterial communities and resistance genes on microplastics to antibiotics and heavy metals in sewage environment
Polyvinyl chloride microplastics in sewage enriched pathogenic bacteria and antibiotic resistance genes on their surfaces, and the presence of heavy metals and antibiotics altered but did not eliminate this enrichment over time. The findings suggest microplastics in wastewater environments could facilitate the spread of antibiotic resistance through the microbial community.
Microplastics Enhance the Prevalence of Antibiotic Resistance Genes in Anaerobic Sludge Digestion by Enriching Antibiotic-Resistant Bacteria in Surface Biofilm and Facilitating the Vertical and Horizontal Gene Transfer
This study found that microplastics in sewage sludge promote the spread of antibiotic resistance genes, which make bacteria harder to treat with antibiotics. Microplastics provided a surface for resistant bacteria to grow and helped them share resistance genes with other bacteria. The more microplastics present, the more antibiotic resistance spread, raising concerns about how plastic pollution in wastewater could contribute to the growing antibiotic resistance crisis.
Fragmented Microplastics Synergize with Biological Treatment To Potentiate Antibiotic Resistance Dissemination during Sewage Treatment
Researchers used metagenomic sequencing and high-throughput qPCR across a full sewage treatment chain to show that fragmented microplastics preferentially concentrate clinically relevant antibiotic resistance genes, with MP-bound genes contributing up to 43% of intracellular resistance genes detected in treated effluent, and Acinetobacter emerging as a key resistance indicator.
Size-dependent effects of microplastics on antibiotic resistance genes fate in wastewater treatment systems: The role of changed surface property and microbial assemblages in a continuous exposure mode
Researchers developed a continuous exposure method to evaluate how different sizes of microplastics affect antibiotic resistance gene fate in wastewater treatment, finding that smaller microplastics had greater impacts on microbial communities and resistance gene proliferation.
Microplastics and their role in the emergence of antibiotic resistance in bacteria as a threat for the environment
Researchers reviewed how microplastics act as breeding grounds for antibiotic-resistant bacteria by providing surfaces where bacteria can swap resistance genes with each other — a process called horizontal gene transfer. This dual threat of plastic pollution and antibiotic resistance is compounding into a significant global public health crisis.
Microplastics enhanced the resistant genes spread under disinfectant replacement exposure in partial nitrification-anammox systems
Researchers investigated how alternating disinfectant exposure affects the spread of antibiotic resistance genes on microplastic biofilms in wastewater treatment systems. They found that switching between different disinfectants increased the risk of resistance gene transmission, with PET and polyethylene microplastics serving as vectors for both resistant bacteria and nitrogen-removing microorganisms. The study raises concerns that microplastics in wastewater systems may accelerate the spread of antimicrobial resistance under common disinfection practices.
Microplastics mediates the spread of antimicrobial resistance plasmids via modulating conjugal gene expression
This study found that four common types of microplastics can increase the spread of antibiotic resistance genes between bacteria by up to 200-fold. The microplastics activated stress-response genes in bacteria that promote the sharing of resistance-carrying DNA. This links two major public health threats, showing that microplastic pollution could make antibiotic-resistant infections more common and harder to treat.
Growth and prevalence of antibiotic-resistant bacteria in microplastic biofilm from wastewater treatment plant effluents
Researchers studied antibiotic-resistant bacteria growing in biofilms on microplastic surfaces in wastewater treatment plant effluent. The study found that microplastic biofilms accumulated antibiotic-resistant bacteria including Pseudomonas, Aeromonas, and Bacillus, and that these biofilms harbored higher concentrations of resistance genes compared to surrounding water, suggesting microplastics may serve as reservoirs for antibiotic resistance.