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 Marine microplastics enrich antibiotic resistance genes (ARGs), especially extracellular ARGs: An investigation in the East China Sea
ClearMarine plastisphere selectively enriches microbial assemblages and antibiotic resistance genes during long-term cultivation periods
Researchers placed four types of common microplastics in a marine environment for over 100 days and found that bacterial communities and antibiotic resistance genes accumulated on the plastic surfaces over time. PVC microplastics were particularly effective at concentrating resistance genes, and a key gene-transfer element was found on all plastic types. These results show that microplastics floating in the ocean act as hotspots for antibiotic-resistant bacteria, which could eventually reach humans through seafood or water.
[Microplastic-Induced Alterations to Antibiotic Resistance Genes in Seawater].
Microplastics added to seawater were found to increase the diversity and abundance of antibiotic resistance genes (ARGs) over a 49-day period, with different plastics having different effects. This suggests that microplastics in coastal waters may contribute to the spread of drug-resistant bacteria, posing a risk to public health.
Microplastisphere antibiotic resistance genes: A bird's-eye view on the plastic-specific diversity and enrichment
Microplastics in the environment act as surfaces for microbial communities called microplastispheres, which this review finds are enriched with antibiotic resistance genes (ARGs). The type of plastic, surrounding water chemistry, and co-occurring pollutants all influence which resistance genes accumulate, raising concern that microplastics could be spreading antibiotic resistance through aquatic environments worldwide.
Microplastisphere may induce the enrichment of antibiotic resistance genes on microplastics in aquatic environments: A review
This first meta-analysis of antibiotic resistance gene (ARG) enrichment on microplastics found that ARGs were more abundant on microplastic surfaces than on inorganic substrates or in surrounding water, but less abundant than on natural organic substrates. Freshwater microplastics showed a higher degree of ARG enrichment than those in saline water or sewage.
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.
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.
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.
Plastics in the marine environment are reservoirs for antibiotic and metal resistance genes
Metagenomic analysis of microbial communities on plastic particles from the North Pacific Gyre revealed high abundances of antibiotic resistance genes (ARGs) and metal resistance genes (MRGs) compared to surrounding seawater. The study demonstrates that ocean plastic debris functions as a reservoir and potential long-range vector for resistance genes, posing a global health concern.
Selective enrichment of bacteria and antibiotic resistance genes in microplastic biofilms and their potential hazards in coral reef ecosystems
Researchers found that microplastic surfaces in coral reef waters selectively collect bacteria carrying antibiotic resistance genes, with the concentration of resistant bacteria linked to antibiotic levels in the surrounding water. The bacterial communities on microplastics were enriched for disease-related pathways compared to the surrounding seawater. This means microplastics in marine environments could serve as vehicles for spreading drug-resistant infections, posing risks to both coral ecosystems and human health.
Microplastics are a hotspot for antibiotic resistance genes: Progress and perspective
This review examines growing evidence that microplastics serve as hotspots for antibiotic resistance genes in the environment. Researchers found that microplastics selectively accumulate antibiotic-resistant bacteria and resistance genes on their surfaces across wastewater, aquatic, and terrestrial environments. The dense bacterial communities and concentrated pollutants on microplastic surfaces create favorable conditions for the spread and evolution of antibiotic resistance, raising concerns about potential risks to human health.
Unraveling the role of microplastics in antibiotic resistance: Insights from long-read metagenomics on ARG mobility and host dynamics
Researchers used long-read metagenomics to investigate how microplastics serve as vectors for antibiotic resistance genes in aquatic environments. They found that plasmid-encoded resistance genes varied significantly between microplastic biofilms and surrounding water, highlighting horizontal gene transfer as a key mechanism for resistance gene enrichment on plastic surfaces. The study identified specific bacterial taxa driving this enrichment and revealed that enhanced cell adhesion and transporter activity on microplastics facilitate the spread of antibiotic resistance.
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.
[Effects of Microplastics on Antibiotic Resistance Genes in Estuarine Sediments].
Researchers investigated the effects of three types of microplastics on antibiotic resistance genes (ARGs) in estuarine sediment microcosms, finding that microplastic presence altered the persistence, abundance, and diversity of ARGs as measured by high-throughput quantitative PCR.
Distinct profile of bacterial community and antibiotic resistance genes on microplastics in Ganjiang River at the watershed level
Researchers investigated microplastic pollution and associated bacterial communities, human pathogenic bacteria, and antibiotic resistance genes across the Ganjiang River watershed. They found microplastics were widely distributed with an average of 407 particles per cubic meter, and that microplastic surfaces harbored significantly higher bacterial diversity and more antibiotic resistance genes than surrounding water or sediment.
Microplastics enhance the prevalence of antibiotic resistance genes in mariculture sediments by enriching host bacteria and promoting horizontal gene transfer
Researchers found that polystyrene and PVC microplastics in marine sediments increased the abundance of antibiotic resistance genes by 1.4 to 2.8 times compared to sediment without plastics. PVC was particularly harmful because its chemical additives, including heavy metals and bisphenol A, promoted bacteria to share resistance genes more readily. These findings show that microplastic pollution in oceans is directly contributing to the spread of antibiotic-resistant bacteria, a major public health concern.
Evidence of selective enrichment of bacterial assemblages and antibiotic resistant genes by microplastics in urban rivers
Researchers sampled microplastics from two urban rivers in China and found that the bacterial communities colonizing plastic particles were distinctly different from those in the surrounding water. The microplastic-associated bacteria had lower diversity but higher proportions of biofilm-forming species and functions linked to human disease. Notably, the study found that microplastics selectively enriched antibiotic resistance genes, raising concerns about plastics serving as reservoirs for drug-resistant bacteria.
High-throughput metagenomic profiling of functional and resistome features in estuarine microplastic microbiomes
Scientists studied tiny plastic particles (microplastics) floating in coastal waters in India and found that harmful bacteria, including antibiotic-resistant germs, were growing on their surfaces. These plastic particles act like floating taxis that can carry dangerous microbes from place to place in the water. This matters because people who swim, fish, or eat seafood from these waters could be exposed to these harmful bacteria.
Emerging Antibiotic Resistance Genes in the Aquatic Ecosystems: a Review
A review of 30 studies found antibiotic resistance genes (ARGs) widely distributed across aquatic ecosystems — in surface water, groundwater, wastewater, and notably on plastic and microplastic debris in these environments. Microplastics appear to provide favorable surfaces for the growth and exchange of resistant bacteria, making plastic pollution a potential vector for spreading antibiotic resistance. The findings highlight an understudied intersection between microplastic contamination and the global antibiotic resistance crisis.
Antibiotic resistant bacteria colonising microplastics in the aquatic environment: An emerging challenge
Researchers reviewed how microplastics in aquatic environments act as surfaces where antibiotic-resistant bacteria can grow and swap resistance genes with each other, raising concern that contaminated seafood and water could transfer these hard-to-treat bacteria to humans.
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.
The impact of microplastics on antibiotic resistance genes, metal resistance genes, and bacterial community in aquaculture environment
Researchers discovered that microplastics in fish farming environments carry significantly higher levels of antibiotic resistance genes and disease-causing bacteria like Brucella and Pseudomonas compared to surrounding water. This means microplastics may act as floating platforms that help spread antibiotic-resistant infections through aquaculture, potentially reaching humans who consume the seafood.
[Influencing Factors and Mechanisms of Antibiotic Resistance Gene Enrichment by Microplastics in the Environment].
This review examines how microplastics in the environment serve as carriers for antibiotic resistance genes, enriching and spreading resistant bacteria across air, soil, water, and sediments. Researchers found that the type, surface characteristics, and aging of microplastics all influence how effectively they accumulate resistance genes and facilitate horizontal gene transfer. The findings highlight the need to consider microplastics as an important vector in the environmental spread of antibiotic resistance.
Enrichment of Antibiotic Resistance Genes on Plastic Waste in Aquatic Ecosystems, Aquatic Animals, and Fishery Products
This review examines how plastic waste in water creates surfaces where antibiotic-resistant bacteria thrive and share resistance genes with each other. Microplastics in rivers, oceans, and fish farms were consistently found to harbor more antibiotic resistance genes than natural materials like rocks or sand. Since fish and shellfish can accumulate these microplastic-associated resistant bacteria, there is a risk that drug-resistant infections could reach humans through the seafood supply chain.
[Research progress on the effect of estuary microplastics on antibiotic resistance genes].
This review summarizes research on how microplastics in estuarine environments influence the spread of antibiotic resistance genes (ARGs), focusing on the role of biofilms that form on plastic surfaces. Microplastic biofilms selectively enrich ARG-carrying bacteria and facilitate horizontal gene transfer, increasing the risk of antibiotic resistance dissemination in ecologically and humanly important estuarine zones.