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Papers
61,005 resultsShowing papers similar to Solving the plastic dilemma: the fungal and bacterial biodegradability of polyurethanes
ClearMicrobial and Enzymatic Biodegradation of Polyurethane: From Depolymerization to Monomer Valorization
A review covered microbial and enzymatic degradation of polyurethane, summarizing the microorganisms and enzymes capable of breaking down this widely used plastic. Identifying effective biodegradation pathways is key to developing biological solutions for polyurethane waste management.
An overview on role of fungi in systematic plastic degradation
This review examines the role of fungi in plastic degradation, surveying fungal species and enzymes capable of breaking down common polymers and discussing their potential for sustainable bioremediation of plastic pollution in the environment.
Breaking down the plastics paradox: polymer degrading microorganisms
This review examines microorganisms capable of degrading plastics, cataloging the bacteria and fungi discovered to break down common polymers like polyethylene, polystyrene, and PET. Identifying and harnessing plastic-degrading microbes could provide biological solutions to the accumulation of microplastics in the environment.
Microbial degradation of plastic-A brief review
This review examined microbial degradation of plastics, surveying known plastic-degrading bacteria and fungi and the enzymes they produce, while acknowledging that degradation rates in natural environments remain extremely slow and that biotechnology approaches to accelerating biodegradation require further development.
Microbial Degradation of Plastics and Approaches to Make it More Efficient
This review examines microbial degradation of plastics by bacteria and fungi, focusing on polyethylene, polystyrene, and PET, and discusses methods to make biodegradation more efficient as a potential solution to plastic pollution.
Review on the current status of polymer degradation: a microbial approach
This review catalogued the bacteria and fungi capable of degrading synthetic polymers, identifying dominant species like Pseudomonas and Aspergillus and arguing that microbial enzymes hold significant potential as tools for biological plastic breakdown.
Microbes mediated plastic degradation: A sustainable approach for environmental sustainability
This review examines microbially mediated plastic degradation as a sustainable environmental cleanup strategy, surveying bacterial and fungal species capable of breaking down common polymers and discussing enzymatic pathways and factors limiting practical biodegradation rates.
Microbial enzymes for the recycling of recalcitrant petroleum‐based plastics: how far are we?
This review examines the progress in identifying microbial enzymes capable of breaking down petroleum-based plastics like polyethylene, polystyrene, polyurethane, and PET. Researchers highlight recent advances in using polyester-degrading enzymes to recover raw materials from PET waste through biocatalytic recycling. The study discusses the potential and remaining challenges of using biological approaches to address the growing global problem of plastic waste accumulation.
Microbial Degradation of Plastic Polymers
This review examines microbial degradation pathways for common synthetic plastics including polyethylene, polypropylene, polystyrene, PVC, polyurethane, and PET, describing how mechanical and biological processes fragment plastics into microplastics and how microorganisms can be leveraged to address plastic pollution in aquatic and terrestrial environments.
Microbial biodegradation of plastics: Challenges, opportunities, and a critical perspective
Researchers reviewed microbial biodegradation of synthetic plastics, summarizing the bacterial and fungal species, enzymes, and biochemical pathways capable of breaking down common polymers and arguing that combining microbial approaches with physicochemical methods offers the most promising eco-friendly route to plastic waste remediation.
Microbial plastic degradation: enzymes, pathways, challenges, and perspectives.
This review synthesizes current knowledge on microbial plastic degradation, covering the enzymes and metabolic pathways involved in breaking down major synthetic polymers, the challenges limiting efficient biodegradation, and perspectives for engineering improved microbial solutions to plastic waste.
Aplicação de microrganismos lipolíticos em alimentos e na biodegradação de poliuretanos
This Brazilian study reviewed the application of lipolytic microorganisms and their enzymes in food processing and in the biodegradation of polyurethane plastics. Lipase enzymes from microbes show potential for breaking down plastic materials including polyurethane foam that otherwise persists as microplastic fragments.
Microbial Biodegradation of Plastic: A Noble Approach
This review examines microbial biodegradation of synthetic plastics as an alternative to conventional disposal methods, highlighting the capacity of diverse microorganisms to degrade recalcitrant polymers including those involved in agricultural, construction, health, and consumer goods applications. Researchers survey mechanisms by which bacteria and fungi break down non-degradable synthetic polymers such as polyethylene, polystyrene, and PVC.
Ability of fungi isolated from plastic debris floating in the shoreline of a lake to degrade plastics
Researchers isolated over 100 fungal strains from plastic debris floating in a Swiss lake and tested their ability to degrade polyethylene and polyurethane, finding that none could degrade polyethylene but four species degraded polyurethane. The results highlight the limited capacity of naturally occurring plastic-colonizing fungi to break down the most abundant plastic polymers in the environment.
Fungal potential for the degradation of petroleum-based polymers: An overview of macro- and microplastics biodegradation
This review examines the potential of fungi to break down petroleum-based plastics, highlighting their unique ability to produce enzymes capable of degrading complex polymers. Researchers found that certain fungal species can use plastic materials as their sole carbon and energy source, offering a promising biological approach to plastic waste remediation. The study calls for further research on novel fungal isolates and molecular techniques to enhance plastic biodegradation processes.
Classification and microbes involved in Plastic biodegradation: A review
This review classifies types of plastics and catalogues the bacteria, fungi, and other microbes involved in plastic biodegradation, examining enzymatic mechanisms and conditions that facilitate microbial breakdown of synthetic polymers. The authors argue that microbial biodegradation offers a more sustainable and less hazardous alternative to physical and chemical disposal methods such as landfill and incineration.
Plastics: Environmental and Biotechnological Perspectives on Microbial Degradation
This review explores the environmental challenges of plastic accumulation and the potential for microorganisms to degrade various types of plastics. Researchers summarized recent discoveries of bacteria and fungi capable of breaking down common plastics like polyethylene and PET, though degradation rates remain slow. The study highlights microbial degradation as a promising but still developing biotechnological approach to addressing plastic pollution.
Fungal Bioremediation of Microplastics
This review examines how fungi can be used for bioremediation of plastic pollution, covering the enzymes and metabolic pathways involved in fungal plastic degradation. Fungal approaches complement bacterial strategies and may offer unique capabilities for breaking down certain types of plastics in contaminated environments.
Microorganisms: Promising approach to quench plastic pollution
This review surveys the range of bacteria and fungi — including Pseudomonas, Bacillus, and several fungal phyla — that are capable of degrading plastics including polyethylene, the world's most produced plastic. Microbial biodegradation is presented as a promising complement to physical and chemical recycling methods, with the potential to address plastic pollution already dispersed in the environment. Harnessing these organisms could eventually provide biological tools to break down plastic waste that has entered soils, waterways, and the ocean.
Microbial Biodegradation of Plastics and Microplastics: Enzymatic Mechanisms, Biotechnological Applications, and Ecotoxicological Perspectives
This review examined the enzymatic mechanisms by which microorganisms degrade plastics and microplastics, covering biotechnological applications and ecotoxicological perspectives. Researchers found that certain bacterial and fungal enzymes can break down persistent plastic polymers, positioning microbial biodegradation as a promising sustainable remediation approach, though scalability and environmental deployment remain challenges.
Isolation of a soil bacterium for remediation of polyurethane and low-density polyethylene: a promising tool towards sustainable cleanup of the environment.
A soil bacterium tentatively classified in the Pseudomonas genus was found to biodegrade both polyurethane and low-density polyethylene plastics. The discovery of a single bacterial strain capable of degrading two different types of plastic is a step toward developing practical microbial tools for plastic waste remediation.
Microbes in Plastic Degradation
This review examines how microorganisms can break down common plastics like polyethylene and PET through enzymatic processes. Researchers summarized the key bacterial and fungal species capable of degrading plastics and the conditions that affect degradation rates. The study highlights that while microbial plastic degradation is promising, natural breakdown is slow and more research is needed to make biological solutions practical at scale.
Role of Various Microbes and Their Enzymatic Mechanisms for Biodegradation of Microplastics
This review examines the microbial enzymes and degradation mechanisms responsible for biodegrading microplastic polymers, covering bacterial, fungal, and algal systems that have evolved plastic-degrading capabilities over the past 150 years of plastic production. The authors survey the most promising enzymatic pathways and organisms for biotechnological application in microplastic remediation.
Microbial and Enzymatic Degradation of Synthetic Plastics
This review examines microorganisms and enzymes that show promise for breaking down common synthetic plastics like polyethylene, PET, and polystyrene. While natural biodegradation of these materials is extremely slow, researchers have identified certain bacteria, fungi, and enzymes that can accelerate the process, pointing toward potential biological solutions for plastic pollution.