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61,005 resultsShowing papers similar to Comprehensive assessment of chlorination disinfection on microplastic-associated biofilms
ClearInteractive impacts of microplastics and chlorine on biological stability and microbial community formation in stagnant water
Researchers found that microplastics in stagnant drinking water accelerated chlorine decay and promoted microbial regrowth, with microplastic-associated biofilms harboring opportunistic pathogens and shifting microbial community composition toward potentially harmful species.
Mitigation of microplastic-associated emerging pollutants by chlorination using field-collected microplastic: Antimicrobial-resistant genes and pathogens
This study investigated whether chlorination — the most common water disinfection method — can kill the antibiotic-resistant bacteria and genes that colonize microplastics in the environment. Chlorine treatment reduced antibiotic resistance genes on microplastics by up to 99.7%, but the thick biofilms on plastic surfaces shielded interior bacteria, limiting full disinfection. A concerning side effect was that chlorine caused microplastics to fragment into even smaller particles under 100 micrometers, potentially increasing their biological uptake and spreading disinfection-resistant genetic material further.
Disinfection impacts: Effects of different disinfection treatments on common polymer types to guide the identification of polymers of concern in the water industry
Researchers tested how common water disinfection methods, including chlorination and chloramination, affect seven types of plastic particles at different doses and pH levels. They found that both treatments caused measurable physical and chemical changes to the polymers, with some plastics showing significant surface degradation and chemical alterations. The findings suggest that water treatment processes may unintentionally transform microplastics in ways that could affect their environmental behavior and potential health impacts.
The resistance change and stress response mechanisms of chlorine-resistant bacteria under microplastic stress in drinking water distribution system
Researchers found that microplastics in drinking water pipes can make chlorine-resistant bacteria even more dangerous by boosting their resistance to both antibiotics and disinfectants. Bacteria attached to microplastic surfaces changed their outer coatings and activated stress responses that increased their survival against water treatment chemicals. This is concerning because it means microplastics in water distribution systems could help create superbugs that standard water treatment cannot eliminate.
Microplastic biofilms in water treatment systems: Fate and risks of pathogenic bacteria, antibiotic-resistant bacteria, and antibiotic resistance genes
This review examines how microplastics in drinking water and wastewater treatment plants develop biofilms that harbor dangerous bacteria and antibiotic resistance genes. The biofilm-coated microplastics can protect pathogens from disinfection processes, allowing them to survive treatment and potentially reach tap water. This raises concerns about microplastics serving as vehicles for antibiotic-resistant bacteria in our water supply.
Effects of microplastics on water disinfection and formation of disinfection by-products
This review examines how the presence of microplastics in drinking water and wastewater interferes with chlorination and ozonation disinfection processes, potentially reducing their effectiveness and generating harmful disinfection by-products. Microplastics can leach dissolved organic carbon that reacts with disinfectants, and they serve as refuges for antibiotic-resistant bacteria that may survive standard treatment. The authors call for more realistic laboratory experiments and field studies to properly assess the real-world risks that microplastics pose inside water treatment plants.
The impact of chlorination on the tetracycline sorption behavior of microplastics in aqueous solution
Researchers found that chlorination, a common disinfection step in wastewater treatment, alters the surface chemistry of microplastics and changes their capacity to adsorb tetracycline antibiotics, with chlorinated microplastics showing modified sorption behavior that affects their role as antibiotic carriers.
Investigation of the effect of microplastics on the UV inactivation of antibiotic-resistant bacteria in water
Researchers found that polyethylene and polyvinyl chloride microplastics significantly reduced UV disinfection effectiveness against antibiotic-resistant bacteria, as bacteria associated with microplastic surfaces were shielded from UV exposure, creating a potential public health concern.
Modifications to sorption and sinking capability of microplastics after chlorination
Researchers found that chlorination disinfection at both low and high doses modified the surface chemistry of PE, PET, PS, and PVC microplastics, increasing surface area and reducing hydrophobicity while weakening their capacity to sorb contaminants like ciprofloxacin. The study concluded that chlorination generally reduces the role of microplastics as transport vectors for organic pollutants, though effects on buoyancy varied by polymer type.
Impact of chlorine and UV/H2O2 on microplastics in drinking water
Using chlorine and UV/hydrogen peroxide at dosages realistic for actual drinking water treatment plants, this study assessed whether standard disinfection processes alter microplastics in tap water. The work addresses a critical public health question — whether the water treatment people rely on to make tap water safe actually removes or changes the microplastics that have been detected in treated drinking water.
Chlorination-improved adsorption capacity of microplastics for antibiotics: A combined experimental and molecular mechanism investigation
Researchers found that when microplastics go through chlorine disinfection in water treatment plants, they become better at absorbing antibiotics like tetracycline. Chlorination changes the surface of polystyrene microplastics, making them stickier for these drugs through stronger chemical bonding. This means treated wastewater may contain microplastics loaded with antibiotics, potentially increasing health risks when released into the environment.
Impact of Chlorine or UV/H2O2 on Microplastics Under Conditions Representative of Drinking Water Treatment
Researchers exposed low- and high-density polyethylene microplastics to chlorine and UV/H2O2 at drinking-water-relevant doses and found that surface changes and cytotoxicity increases reported in earlier studies occurred only at far higher doses than used in practice.
Biofilm formation on microplastics in wastewater: insights into factors, diversity and inactivation strategies
This study investigated how bacteria form biofilms on different types of microplastics in wastewater, finding that polyethylene supported the most biofilm growth, especially in dark, warm, oxygen-rich conditions. The biofilms contained bacteria from groups that include potential human pathogens, and different plastic types supported different microbial communities. This matters because microplastics coated in bacterial biofilms could transport harmful microorganisms through water systems and into the environment.
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.
Adsorption of the antimicrobial triclosan to microplastics impacts biofilm and planktonic microbial communities in freshwater
Researchers tested how triclosan—an antimicrobial compound—adsorbs to microplastics and what effect this has on microbial biofilm communities in freshwater. Triclosan-loaded microplastics shifted microbial community composition and increased abundance of antibiotic-resistant bacteria in biofilms, demonstrating that microplastics acting as vectors for antimicrobials can restructure freshwater microbial ecosystems.
Recent advances in the relationships between biofilms and microplastics in natural environments
This review summarizes how microorganisms form biofilms on the surface of microplastics in water, changing the particles' physical properties and helping to spread bacteria and genes across ecosystems. These biofilm-coated microplastics can carry harmful microbes into new environments, raising concerns about waterborne disease transmission and the effectiveness of current water treatment methods.
Biofilm formation and its implications on the properties and fate of microplastics in aquatic environments: A review
Researchers reviewed how microplastics in water attract and support communities of bacteria and other microorganisms that form biofilms — living coatings that alter the plastic particles' movement, help them carry pathogens, and affect how toxic chemicals attached to the plastic are absorbed by living things. Understanding this "plastisphere" ecosystem is critical for predicting where microplastics go and how harmful they become.
Unique Bacterial Community of the Biofilm on Microplastics in Coastal Water
Researchers compared bacterial communities forming biofilms on steel, silica, and PVC microplastic surfaces in coastal seawater and found that biofilm composition differed by material type. This shows that the type of plastic surface influences which microbial communities colonize it, with implications for how microplastics may spread specific bacteria.
Microplastic biofilm in fresh- and wastewater as a function of microparticle type and size class
Researchers compared the biofilm communities that form on microplastics of different types and sizes in both freshwater and wastewater, finding that biofilm composition was influenced by particle type, size, and water source. These findings advance understanding of the plastisphere — the microbial community unique to plastic surfaces — and its potential role in spreading microorganism-associated risks.
Microplastics in fresh- and wastewater are potential contributors to antibiotic resistance - A minireview
Researchers reviewed the link between microplastic pollution and the spread of antibiotic resistance in freshwater environments, finding that microplastic surfaces host unique bacterial communities enriched in antibiotic-resistant bacteria and the resistance genes they can share with other microbes. The close packing of bacteria in these plastic-surface biofilms may accelerate the spread of drug-resistant pathogens through drinking water sources, though the full health implications remain poorly understood.
Microplastic-affected pathogens in drinking water supply systems: Survival mechanisms, ecological impacts and control challenges
This review synthesized evidence on how microplastics in drinking water supply systems affect pathogen behavior, focusing on opportunistic pathogens. Microplastics were found to enhance pathogen survival, promote antibiotic resistance gene transfer, and facilitate biofilm formation, with implications for the safety of treated drinking water.
Colonization characteristics and surface effects of microplastic biofilms: Implications for environmental behavior of typical pollutants
This review examines how bacteria colonize microplastic surfaces in water, forming biofilms that change how the plastics behave in the environment. These biofilms alter the surface properties of microplastics and affect how they absorb and transport heavy metals and other pollutants. Understanding biofilm formation on microplastics is important because it can make the particles more dangerous by concentrating toxic substances that could eventually enter the food chain.
Can microplastics and disinfectant resistance genes pose conceivable threats to water disinfection process?
This review examines how microplastics in water supplies interact with disinfection resistance genes (DRGs) in bacteria, creating a compounding threat to water safety. Microplastics provide surfaces where resistant bacteria can form biofilms and exchange resistance genes, and they can locally reduce the effective concentration of disinfectants — making standard water treatment less effective. The concern is that as both microplastic pollution and disinfectant use grow, we may be inadvertently breeding harder-to-kill pathogens in our drinking water systems.
Total coliform and Escherichia coli in microplastic biofilms grown in wastewater and inactivation by peracetic acid
Researchers found that microplastics support the growth of fecal indicator bacteria including E. coli in biofilms, and that these biofilm communities are more resistant to disinfection by peracetic acid than free-floating cells. The findings support concerns that microplastics act as vectors for pathogens and complicate wastewater disinfection.