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61,005 resultsShowing papers similar to Classification and microbes involved in Plastic biodegradation: A review
ClearMicrobial 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.
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 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.
Biodegradation of typical plastics and its mechanisms
This review summarizes the mechanisms by which common plastic types are broken down by bacteria, fungi, and other microorganisms in the environment. Despite their chemical stability, many plastics can be degraded — though slowly — with the pace depending on environmental conditions and plastic type. The paper provides a foundation for developing faster biodegradation strategies to reduce plastic pollution.
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.
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 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.
Harnessing Microorganisms for Microplastic Degradation: A Sustainable Approach to Mitigating Environmental Pollution
This review surveys microorganisms—bacteria, fungi, and other taxa—capable of degrading microplastics, examining the enzymes, metabolic pathways, and environmental conditions involved, and assessing the practical potential of harnessing these organisms for bioremediation of plastic pollution.
Microbial Degradation of Micro‐Plastics
This review examines the role of naturally occurring microorganisms including bacteria, fungi, and algae in degrading microplastics, discussing the enzymatic mechanisms involved, the species identified as effective plastic degraders, and the prospects for applying microbial degradation pathways in bioremediation strategies.
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.
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.
Microbe‐mediated biodegradation of microplastics from wastes
Researchers examined microbe-mediated biodegradation of microplastics from waste, reviewing bacterial and fungal species capable of breaking down various plastic polymers and discussing enzymatic mechanisms that could be harnessed for bioremediation strategies.
Microbial Degradation and Valorization of Plastic Wastes
This review covers recent advances in microbial and enzymatic degradation of synthetic plastic wastes, summarizing the microorganisms and enzymes capable of attacking different polymer types and assessing the prospects for biological plastic waste treatment at scale.
Bioremediation of plastics by the help of microbial tool: A way for control of plastic pollution
This review covers how bacteria and fungi can be used to break down plastic waste, including microplastics, through natural biological processes. Various microorganisms can degrade different types of plastics by producing specific enzymes, though the process is slow and depends on the plastic type and environmental conditions. While biological degradation shows promise for reducing microplastic pollution in soil and water, much more research is needed to make it effective enough to address the scale of the problem.
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.
Role of Novel Biological Agents in Plastic Degradation and Mitigation Approach towards Bioplastics
This review examines the role of novel biological agents — including bacteria, fungi, and engineered microorganisms — in degrading synthetic plastics and proposes bioplastics as a mitigation strategy to reduce persistent polymer accumulation in the environment. The authors outline the enzymatic mechanisms involved in breaking down major plastic types and discuss the potential of combining biological degradation with bioplastic adoption.
Microbial Degradation of Plastics
This review covers microbial species capable of degrading synthetic plastics, examining the enzymes and metabolic pathways involved and the environmental conditions that influence breakdown rates. While microbial degradation offers a promising long-term remediation strategy, the review concludes that current rates are far too slow to address the scale of plastic accumulation in the environment.
Biodegradation of plastic by some Microorganisms as influenced by Chemical factors
This study examined microbial and enzymatic biodegradation of plastic materials, testing which fungi and bacteria can break down common plastics under various chemical conditions. Fungi like Penicillium and Aspergillus showed capacity to degrade plastic, offering potential biological pathways for plastic waste management.
Recent Advancements and Mechanism of Plastics Biodegradation Promoted by Bacteria: A Key for Sustainable Remediation for Plastic Wastes
This review highlights recent discoveries of microbial enzymes capable of degrading various plastics, discussing bacterial biodegradation mechanisms as a sustainable remediation strategy for addressing accumulating plastic waste in landfills and water bodies.
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.
Plastic biodegradation: Frontline microbes and their enzymes
Researchers reviewed microbial biodegradation of synthetic plastics — including PE, PP, PS, and PET — cataloguing the insects, bacteria, and fungi capable of breaking down these polymers along with the enzymatic mechanisms involved, and outlining paths forward including metabolic pathway engineering and molecular cloning to improve degradation rates.
Characteristic Features of Plastic Microbial Degradation
This book chapter reviews the characteristics of microbial plastic degradation, covering the enzymes, metabolic pathways, and environmental conditions that affect breakdown rates for different polymer types. Understanding microbial degradation mechanisms is foundational to developing biological solutions for microplastic pollution.
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.
The Biodegradation of Plastic by Microorganisms
This review examines how the chemical composition of plastics influences their susceptibility to biodegradation by microorganisms, discussing the diverse biophysical-chemical properties of synthetic polymers that affect microbial degradation rates across different environmental contexts.