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61,005 resultsShowing papers similar to Rapid biodegradation of microplastics generated from bio-based thermoplastic polyurethane
ClearUnderstanding visible light and microbe-driven degradation mechanisms of polyurethane plastics: Pathways, property changes, and product analysis
Researchers found that polyurethane plastics break down in water through a combination of microbial action and light exposure, producing secondary microplastics as they degrade. This study reveals a previously underappreciated source of microplastic pollution, since polyurethane is widely used in coatings, foams, and other products that often end up in waterways.
Polyurethane degradation by extracellular urethanase producing bacterial isolate Moraxella catarrhalis strain BMPPS3.
A soil bacterium, Moraxella catarrhalis strain BMPPS3, was found capable of degrading polyurethane plastic, achieving 67% weight reduction in 30 days. The discovery of naturally occurring bacteria that break down plastics offers potential for biological remediation of polyurethane waste, which is widely used in construction, furniture, and automotive applications.
The effect of biodegradable plastics on microplastic accumulation and exposure
Researchers developed a comprehensive method to quantify microplastic accumulation from biodegradable polymers in natural environments, examining whether biodegradable alternatives actually reduce plastic loads compared to conventional polymers under real-world outdoor conditions.
A progress update on the biological effects of biodegradable microplastics on soil and ocean environment: A perfect substitute or new threat?
This review examines whether biodegradable plastics, often marketed as eco-friendly alternatives, actually break down safely in the environment. The evidence shows that biodegradable plastics often fragment into microplastics rather than fully decomposing, and these biodegradable microplastics can harm soil organisms, marine life, and disrupt nutrient cycles. The findings suggest that simply switching to biodegradable plastics may not solve the microplastic pollution problem and could introduce new environmental risks.
A review of biodegradation and formation of biodegradable microplastics in soil and freshwater environments
Researchers reviewed how biodegradable plastics break down in soil and freshwater, finding that incomplete degradation by microorganisms can still produce tiny biodegradable microplastic particles that persist in the environment — meaning "biodegradable" doesn't always mean safe or fast-disappearing.
Effect of Polymer Properties on the Biodegradation of Polyurethane Microplastics
Researchers investigated biodegradation of different thermoplastic polyurethane formulations in compost, finding that the ester bond chemistry of polyurethanes enables some degree of hydrolytic degradation. The rate and extent of biodegradation varied substantially with polymer chemistry, with ester-based polyurethanes degrading faster than ether-based types.
Effect of digestion system on microstructures of microplastics from biodegradable polyesters and impact of these microplastics on microorganisms in digestion system
Researchers systematically examined how the digestive system alters the surface microstructure and chemical composition of biodegradable microplastics (including PBAT and PLA products), and reciprocally how these bio-microplastics affect probiotics and other digestive microorganisms, finding that both virgin and UV-aged biodegradable plastics interact with the gut environment.
Solving the plastic dilemma: the fungal and bacterial biodegradability of polyurethanes
This review examined the biodegradability of polyurethane by fungi and bacteria, identifying promising microbial species and enzymes capable of breaking down this widely used but environmentally persistent plastic polymer.
Polylactic acid synthesis, biodegradability, conversion to microplastics and toxicity: a review
Researchers reviewed polylactic acid (PLA), a popular plant-based "biodegradable" plastic used in packaging and agriculture, finding that while it breaks down inside the body, it does not fully degrade under natural outdoor or aquatic conditions — and in fact fragments into microplastics faster than conventional petroleum-based plastics. This challenges the assumption that bioplastics are a straightforward environmental solution.
Bacteria as Ecological Tools: Pioneering Microplastic Biodegradation
This systematic review examines how bacteria can be used to biologically break down microplastic particles. The researchers identified several bacterial species capable of degrading different types of plastics, offering a potential natural solution to microplastic pollution. Finding biological methods to break down microplastics could reduce the amount of these particles that accumulate in our environment and food chain.
Unravelling the ecological ramifications of biodegradable microplastics in soil environment: A systematic review
Researchers reviewed 85 studies on biodegradable microplastics in soil, finding that when biodegradable plastics fail to fully break down they can disrupt soil structure, nutrient cycling, and microbial life in ways that depend heavily on concentration and plastic type. The review highlights that "biodegradable" plastics are not a simple fix for microplastic pollution in agricultural soils.
A community of marine bacteria with potential to biodegrade petroleum-based and biobased microplastics
Researchers showed that a consortium of marine bacteria could partially biodegrade both conventional low-density polyethylene and biobased polyethylene terephthalate microplastic films over 45 days, with spectroscopic and chemical evidence confirming surface changes and early-stage degradation.
Design of Biodegradable PU Textile Coating
Researchers developed a biodegradable polyurethane coating for textiles as an alternative to conventional coatings that contribute to microplastic pollution when they end up in landfills. The new coating achieved nearly 60% biodegradation in soil while maintaining acceptable water barrier and mechanical properties. The study demonstrates that functional textile coatings can be designed to break down naturally, reducing their long-term environmental impact.
Ecotoxicity of Biodegradable Microplastics and Bio-based Microplastics: A Review of in vitro and in vivo Studies
This review examines whether "eco-friendly" biodegradable and bio-based plastics are truly safer than conventional plastics when they break down into microplastics. The findings show that many biodegradable plastics, including popular types like PLA and PBAT, can still cause harm to plants and aquatic organisms, suggesting that simply switching to biodegradable materials does not eliminate microplastic risks.
Microplastic pollution induces algae blooms in experimental ponds but bioplastics are less harmful
Researchers found that petroleum-derived thermoplastic polyurethane microplastics consistently induced algal blooms in experimental ponds at high concentrations, while biodegradable bioplastic alternatives caused less ecological disruption, suggesting bioplastics may pose lower risks to aquatic ecosystems.
Differential responses of soil microbial community structure and function to conventional and biodegradable microplastics
Scientists compared how tiny pieces of regular plastics and "biodegradable" plastics affect helpful bacteria in soil after 6 months. They found that biodegradable plastics actually disrupted soil bacteria more than regular plastics, changing the microbes that help plants grow and cycle nutrients. This matters because these soil bacteria are crucial for growing healthy food, so switching to biodegradable plastics might not be the simple environmental solution we hoped for.
Bioplastics: Missing link in the era of Microplastics
Researchers examined whether bioplastics, often promoted as eco-friendly alternatives to conventional plastics, also break down into microplastics. They found that polyhydroxyalkanoate bioplastic films formed microplastic particles in water environments similar to conventional plastics. The study highlights that biodegradable plastics may not solve the microplastic problem and calls for more research into how quickly bioplastics actually degrade and what effects their microplastic fragments have on ecosystems.
Exploring Microorganisms from Plastic-Polluted Sites: Unveiling Plastic Degradation and PHA Production Potential
Researchers screened microorganisms from plastic-polluted sites for their ability to break down conventional plastics and produce a biodegradable alternative called PHA. They identified several bacterial strains capable of degrading synthetic polymers and simultaneously producing this bio-based plastic from waste materials. The study highlights the potential for using naturally adapted microbes from contaminated environments as tools for both plastic cleanup and sustainable material production.
Ecological implications of biodegradable and conventional microplastics: Dissolved organic matter bioavailability and microbial response in marine systems
Researchers compared the dissolved organic matter released by biodegradable and conventional microplastics and assessed its bioavailability to marine microbial communities. They found that biodegradable plastics like PLA released organic matter that was more readily used by microorganisms, which altered microbial community composition. The study suggests that while biodegradable plastics break down faster, their leached compounds may have distinct and potentially significant ecological effects in marine environments.
Incorporation of polylactic acid microplastics into the carbon cycle as a carbon source to remodel the endogenous metabolism of the gut
Researchers discovered that gut bacteria can break down so-called biodegradable PLA microplastics and incorporate the carbon into their own metabolism, fundamentally altering the gut's energy balance. This process reduced beneficial short-chain fatty acids that fuel gut lining cells and caused decreased appetite and weight loss in mice, suggesting that biodegradable plastics may not be as harmless inside the body as assumed.
Degradation of biodegradable plastic films in soil: microplastics formation and soil microbial community dynamics
Scientists tracked what happens when biodegradable PBAT plastic films break down in soil over 180 days and found they release microplastics that peaked before declining. Fungi broke the films into smaller pieces while bacteria consumed the fragments, suggesting that even plastics marketed as biodegradable generate microplastics during their breakdown, though soil microbes can eventually help clean them up.
A review on fate and ecotoxicity of biodegradable microplastics in aquatic system: Are biodegradable plastics truly safe for the environment?
This review examines whether biodegradable plastics are truly safe for aquatic environments, finding that they can break down into microplastics faster than conventional plastics and cause comparable or even greater harm to algae, invertebrates, and fish. The findings suggest that switching to biodegradable plastics alone will not solve the microplastic pollution problem, and these particles can still enter the human food chain through contaminated seafood.
Can biodegradable polymers make microplastics?
Researchers investigated whether biodegradable polymers can form microplastics during their intended use and degradation, finding that several biodegradable materials do indeed fragment into micro- and nanoscale particles before fully mineralizing. The study raises important questions about whether "biodegradable" plastics fully solve the microplastic problem.
Bacterial screening in Indian coastal regions for efficient polypropylene microplastics biodegradation
Researchers screened marine bacteria from two coastal regions in India for their ability to break down polypropylene microplastics. They identified several bacterial strains that caused measurable weight loss and structural changes in polypropylene particles over a 60-day period. The study suggests that naturally occurring marine bacteria could potentially be harnessed for biological approaches to reducing microplastic pollution in ocean environments.