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61,005 resultsShowing papers similar to Biodegradation of Poly(Ethylene Terephthalate) Microplastics by Baceterial Communities From Activated Sludge
ClearBiodegradation of Poly(Ethylene Terephthalate) Microplastics by Baceterial Communities From Activated Sludge
Scientists isolated bacteria from wastewater treatment sludge that can biodegrade PET plastic, used in plastic bottles and food packaging. The bacteria broke down PET microplastics over a 60-day period, pointing toward a potential biological tool for removing plastic contamination from water treatment systems.
Biodegradation of polyethylene terephthalate microplastics by bacterial communities from activated sludge
Bacterial communities from activated sludge were shown to grow on PET microplastics as a sole carbon source and achieved measurable biodegradation of heat-pretreated PET fragments in a standardized CO₂ evolution test, identifying activated sludge as a source of PET-degrading microbes.
Enhanced degradation of polyethylene terephthalate (PET) microplastics by an engineered Stenotrophomonas pavanii in the presence of biofilm
Scientists engineered a biofilm-forming bacterium to break down PET microplastics (the type found in water bottles and food containers) at room temperature. The engineered bacteria achieved significant PET degradation over 30 days and also worked on other polyester plastics, offering a potential biological solution for cleaning up microplastic pollution in water environments.
Degradation of polyethylene terephthalate (PET) plastics by wastewater bacteria engineered via conjugation
Scientists engineered wastewater bacteria to break down PET plastic, one of the most common microplastic types, by transferring plastic-degrading genes through a natural DNA-sharing process. The modified bacteria could partially degrade a consumer PET product in 5 to 7 days. This proof-of-concept approach could help reduce the amount of microplastics released from wastewater treatment plants into the environment.
Biological Degradation of Polyethylene Terephthalate by Rhizobacteria
Researchers isolated rhizobacteria — bacteria associated with plant roots — that can biodegrade polyethylene terephthalate (PET) plastic. This finding suggests that soil bacteria near plants may contribute to plastic breakdown in contaminated soils, though degradation rates remain slow.
Marine hydrocarbon-degrading bacteria breakdown poly(ethylene terephthalate) (PET)
Scientists used microcosm studies to investigate whether marine hydrocarbon-degrading bacteria can break down PET plastic, finding that specific bacterial strains could colonize and degrade PET surfaces, offering insights into natural plastic biodegradation in the ocean.
Enzymatic Degradation of Polyethylene Terephthalate Plastics by Bacterial Curli Display PETase
Researchers engineered bacteria to display a PET-degrading enzyme on their surface, creating a reusable biocatalyst capable of breaking down polyethylene terephthalate plastics. The system worked under various conditions, remained stable for at least 30 days, and could even degrade PET microplastics in wastewater and highly crystalline consumer plastic waste. This biological approach offers a promising environmentally friendly alternative for plastic recycling and waste treatment.
Examining and identifying bacteria-mediated polyethylene terephthalate bottle waste degradation Byprops
Researchers isolated Bacillus subtilis from PET plastic waste dump sites and demonstrated that the bacterium can degrade polyethylene terephthalate microplastics over six months, with UV-pretreated PET showing the most pronounced changes including new alkyl aryl ether and alkene groups detected by FTIR and GC-MS. The findings suggest soil bacteria could offer a biodegradable solution for eliminating PET from plastic-contaminated sites.
Degradation of PET plastic with engineered environmental bacteria
Scientists engineered a soil bacterium to break down PET plastic, one of the most common plastics in food packaging and textiles, by giving it the ability to produce and secrete a powerful plastic-degrading enzyme. This is one of the first demonstrations of a living microorganism that can directly consume PET as a food source, which could lead to more sustainable recycling approaches.
Plastic-Degrading Microbial Consortia from a Wastewater Treatment Plant
Researchers isolated bacteria from a wastewater treatment plant that can break down common plastics including polyethylene and polystyrene, some of the hardest plastics to recycle. The microbial communities worked together to degrade the plastics more effectively than individual bacterial strains. While biological plastic degradation is still slow compared to the scale of pollution, identifying these bacteria is a step toward developing biotechnology solutions for plastic waste cleanup.
Insights into the microbial response of anaerobic granular sludge during long-term exposure to polyethylene terephthalate microplastics
Researchers investigated how polyethylene terephthalate microplastics affect anaerobic granular sludge used in wastewater treatment over 84 days. The study found that at relatively low concentrations, PET microplastics had minimal impact, but at higher concentrations they disrupted the microbial community structure and reduced the efficiency of the anaerobic treatment process.
Sustainable solution for microplastic removal: Sequential biodegradation and detoxification of polyethylene terephthalate microplastics by two natural microbial consortia
Researchers developed a two-stage approach using natural microbial communities to break down PET microplastics and neutralize their toxic byproducts. The first bacterial-fungal group achieved 28% degradation over 60 days, while a second group of bacteria further processed the breakdown products, reducing their toxicity. The study demonstrates that sequential microbial treatment could be a practical, eco-friendly strategy for addressing PET microplastic pollution.
Impact of Polyethylene Terephthalate Microplastics on Aerobic Granular Sludge Structure and EPS Composition in Wastewater Treatment
Researchers investigated how PET microplastics affect the structure and function of aerobic granular sludge used in wastewater treatment. Higher microplastic concentrations led to changes in granule size, altered the composition of extracellular polymeric substances, and shifted microbial community structure. The findings suggest that microplastic contamination in wastewater could compromise the stability and efficiency of biological treatment processes.
Degradation of PET Plastics by Wastewater Bacteria Engineered via Conjugation
Researchers demonstrated a proof-of-concept approach for reducing PET microplastic pollution in wastewater by engineering bacteria in situ via conjugation to express PET-degrading enzymes. The study used a broad-host-range conjugative plasmid to transfer PET hydrolase genes into native wastewater bacterial communities.
Efficient biodegradation of Polyethylene terephthalate (PET) plastic by Gordonia sp. CN2K isolated from plastic contaminated environment
Researchers isolated a bacterium called Gordonia sp. CN2K from a waste management site that can break down PET plastic, one of the most widely used and persistent types of plastic. Over 45 days, the bacterium degraded over 40% of PET microplastic by using it as its sole carbon and energy source. The findings suggest that naturally occurring microorganisms could be harnessed to help address the growing problem of microplastic pollution in the environment.
A review on microbial bioremediation of polyethylene terephthalate microplastics
This review focuses on microbial biodegradation of PET microplastics — the plastic used in bottles and synthetic textiles — detailing the specific enzymes (PETase and MHETase) that bacteria use to break the polymer down into its chemical building blocks. Biological degradation offers a lower-energy, more environmentally gentle alternative to chemical recycling or landfill, and understanding the microbial mechanisms involved is key to developing scalable bioremediation solutions for one of the most pervasive microplastic types.
Biodegradation of Poly(ethylene terephthalate) by Bacillus safensis YX8
Researchers isolated a PET-degrading bacterial strain, Bacillus safensis YX8, from the surface of plastic waste and demonstrated its ability to break down PET nanoparticles. The study identified the degradation products as terephthalic acid and related compounds, suggesting this bacterium could contribute to environmentally friendly approaches for managing PET plastic waste.
Current Knowledge on Polyethylene Terephthalate Degradation by Genetically Modified Microorganisms
This review covers genetically modified microorganisms engineered to degrade polyethylene terephthalate, examining how bioengineering of enzymes such as PETase and enhanced expression systems can overcome the low biodegradation rates of wild-type microorganisms toward this ubiquitous plastic.
In vivo degradation of polyethylene terephthalate using microbial isolates from plastic polluted environment.
Researchers isolated four microbial strains from plastic waste dumping sites and tested their ability to degrade polyethylene terephthalate in vivo, finding measurable weight loss and surface modification of PET films over 30 days, with Aspergillus species demonstrating the highest degradation efficiency.
Characterization of plastic degrading bacteria isolated from sewage wastewater
Researchers isolated bacteria from sewage wastewater that can degrade plastic, with two Pseudomonas strains achieving 25% weight loss of plastic pieces over 120 days. Chemical analysis confirmed the bacteria were breaking down and transforming the plastic polymer bonds. These plastic-eating bacteria could offer a green biotechnology approach to reducing microplastic pollution in wastewater systems.
Microplastic pollution in aquatic environments: a systematic review of bacterial degradation efficacy, mechanisms, and future pathways
Scientists reviewed 80 studies and found that certain bacteria can break down microplastics—tiny plastic particles polluting our water—by "eating" them with special enzymes. The bacteria work best on some plastics like PET (used in water bottles), breaking down up to 50% in just days, but struggle with tougher plastics like grocery bags. While this bacterial cleanup shows promise for reducing plastic pollution that can enter our food chain, it currently only works well in controlled lab settings, not in real oceans and rivers.
Microbial Transformation of Polyethylene Terephthalate Microplastics by Wetland-Derived Microbial Communities: Implications for Coastal Sediment Systems
Researchers exposed PET plastic fibers to a wetland sediment microbial consortium for 60 days, finding 13.7% weight loss driven by synergistic interactions among taxa like Acinetobacter and Pseudomonas, suggesting coastal wetlands harbor natural PET-degrading communities with potential for nature-based plastic remediation strategies.
Efficient Depolymerization and Low-Toxicity Leaching of Polyester Microplastics through Alkali-Hydrothermal Treatment of Sewage Sludge
Researchers developed an alkali-hydrothermal treatment method that degraded 82% of PET microplastics trapped in sewage sludge, converting them into low-toxicity dissolved organic matter. The approach works by leveraging alkalinity, metal ions, and organic matter naturally present in sludge to break down plastic through hydrolysis and radical oxidation, offering a practical strategy for reducing microplastic contamination before sludge is applied to agricultural land.
Biodegradation of Microplastic Derived from Poly(ethylene terephthalate) with Bacterial Whole-Cell Biocatalysts
Engineered bacterial whole-cell biocatalysts were used to biodegrade PET microplastics under alkaline conditions, with the strain using PET as a sole carbon source and producing monomers that did not accumulate due to continuous cellular metabolism. The study demonstrates a combined enzymatic-microbial approach that overcomes product inhibition in enzymatic PET degradation.