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20 resultsShowing papers similar to Prospection of marine filamentous fungi in the biodegradation of microplastic
ClearThe Role of Marine Fungi in Degradation of Microplastic and Plastics – a Review
This review examines the role of marine fungi in the biodegradation of microplastics and bulk plastics, synthesising literature on over 400 known plastic-degrading microorganism species and highlighting the most significant fungal groups capable of decomposing plastic materials in marine environments.
The Potential Role of Marine Fungi in Plastic Degradation – A Review
This review examined the potential role of marine fungi in plastic degradation, highlighting that while terrestrial fungi can metabolize some plastic types, marine fungal-plastic interactions remain largely unexplored despite fungi's known ability to break down recalcitrant compounds.
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.
Bioprospecting of Mangrove Filamentous Fungi for the Biodegradation of Polyethylene Microplastics
Researchers screened mangrove-associated filamentous fungi for the ability to biodegrade polyethylene microplastics, identifying candidate strains with plastic-degrading potential. Selected fungal isolates showed measurable polyethylene degradation activity, expanding the known roster of plastic-degrading organisms and highlighting mangrove ecosystems as a source of environmentally relevant bioremediation agents.
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.
Fungal Degradation of Microplastics—An Environmental Need
This review highlights fungi as an underexplored but promising tool for breaking down microplastics in the environment, noting that fungal enzymes can degrade plastics that bacteria struggle with. As conventional physical and chemical methods fall short of addressing the scale of microplastic pollution, fungal biodegradation could offer a practical, scalable complement to existing cleanup strategies.
Biodegradation of Plastics Induced by Marine Organisms: Future Perspectives for Bioremediation Approaches
This review explores how marine organisms, including bacteria and fungi, can biodegrade plastic pollution in ocean environments. Researchers surveyed the current evidence on biofouling and enzymatic breakdown of different plastic types by marine life. The study suggests that harnessing these natural biodegradation processes could offer a promising bioremediation approach, though significant research gaps remain before practical applications are feasible.
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.
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.
Biodegradation of polyethylene microplastics by the marine fungus Zalerion maritimum
Researchers tested whether the marine fungus Zalerion maritima can biodegrade polyethylene microplastics, finding evidence of polymer degradation through weight loss and surface modification, suggesting marine fungi as natural plastic-degrading agents.
Myco-degradation of microplastics: an account of identified pathways and analytical methods for their determination
This review examined fungal degradation pathways for microplastics and the analytical methods used to assess biodegradation progress. The study highlights that fungi possess diverse enzymatic systems, including extracellular enzymes, capable of breaking down various plastic polymers, suggesting that fungal bioremediation could be a promising approach for reducing microplastic pollution in the environment.
BIORREMEDIAÇÃO DE MICROPLÁSTICOS COM A COLABORAÇÃO DO FUNGO Zalerion maritimum
Researchers investigated whether the marine fungus Zalerion maritimum can bioremediate microplastics in ocean environments, noting that plastic pollution primarily originates from terrestrial sources. The study is a Brazilian-language paper exploring fungal biotechnology as a potential tool for reducing plastic contamination in marine ecosystems.
BIORREMEDIAÇÃO DE MICROPLÁSTICOS COM A COLABORAÇÃO DO FUNGO Zalerion maritimum
This companion paper (in Portuguese) describes the potential of the marine fungus Zalerion maritimum for breaking down microplastics in the ocean. Fungal bioremediation represents an emerging biological approach to reducing plastic pollution in aquatic environments.
The threat of microplastics and microbial degradation potential; a current perspective
This review covers the growing threat of microplastics in marine environments, where they enter the food chain and can transfer to humans along with pathogenic organisms, causing various toxic effects. The paper also explores how bacteria and fungi found in ocean environments could be harnessed to biodegrade different types of plastics as a future strategy for reducing microplastic pollution.
Plastic-inhabiting fungi in marine environments and PCL degradation activity
Researchers collected fungi growing on plastic waste along Korean coastlines and tested their ability to break down a biodegradable plastic called polycaprolactone (PCL), finding that 87 out of 108 species identified showed some degradation ability. This suggests that ocean plastic surfaces host a diverse community of fungi that could potentially be harnessed to biologically break down plastic pollution in marine environments.
Myco-remediation of plastic pollution: current knowledge and future prospects
Researchers reviewed the growing body of evidence showing that fungi can break down common plastics — including polyethylene, polystyrene, and polypropylene — by secreting specialized enzymes that attack and mineralize plastic polymers, with many effective species coming from the Aspergillus and Penicillium families. The review calls for metagenomic approaches to discover more plastic-degrading fungi and develop them into practical bioremediation tools.
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.
Assessment of Microplastic Degrading Potential of Fungal Isolates from an Estuary in Rivers State, Nigeria
Scientists from Nigeria tested whether fungi isolated from an estuary could degrade different types of microplastic particles, finding that several fungal species caused measurable weight loss and surface changes in the plastics. This adds to evidence that environmental fungi have the potential to break down plastic pollution biologically.
Biodegradation of different types of microplastics: Molecular mechanism and degradation efficiency
This review examines how bacteria, fungi, and algae can break down different types of microplastics through their enzymes, and compares the degradation efficiency of various microbial strains. Understanding these biological breakdown pathways is important because they could be developed into practical solutions for reducing the persistent microplastic pollution that threatens ecosystems and human health.
Planktonic marine fungi: A review
This review summarizes the ecology of planktonic marine fungi, which play important roles as decomposers and parasites in ocean ecosystems. Marine fungi also colonize microplastic particles as part of the plastisphere, where they may contribute to plastic degradation.