We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
Papers
61,005 resultsShowing papers similar to Green Remediation of Microplastics Using Bionanomaterials
ClearRemediation of microplastics using bionanomaterials: A review
This review compiles bionanomaterial-based approaches for remediating microplastic pollution, highlighting eco-friendly nanotechnological strategies developed to control and remove microplastics from the environment.
Nanobiomaterials-Based Environmental Bioremediation: A Special Focus on Microplastics
This chapter reviews nanotechnology-based biomaterials for bioremediation of environmental microplastic pollution, examining collective microbial power technologies and green nanomaterial approaches for removing plastic particles from contaminated environments. The authors assess current bionanomaterial techniques and their advantages and disadvantages, and outline future directions for achieving complete microplastic purging from environmental systems.
Nanomaterials for microplastic remediation from aquatic environment: Why nano matters?
This review examines how nanomaterials such as photocatalysts, adsorbents, and membrane filters can be used to remove microplastics from aquatic environments, highlighting why nanoscale properties offer advantages over conventional remediation approaches.
Nanomaterials for microplastics remediation in wastewater: A viable step towards cleaner water
This review examines how nanomaterials, tiny engineered particles with high surface area and reactivity, can be used to remove microplastics from water more effectively than traditional methods like filtration and sedimentation. While promising, these technologies face challenges including high production costs, potential toxicity of the nanomaterials themselves, and difficulty scaling up from lab to real-world applications. Improving these methods is important because current water treatment often fails to remove the smallest and most harmful microplastic particles.
Review of green technologies for the removal of microplastics from diverse environmental sources
This review surveys green technologies being developed to remove microplastics from water, soil, air, and biological systems. Researchers evaluate methods including bioremediation, advanced filtration, and electrochemical approaches as alternatives to conventional treatment. The study emphasizes the need for scalable, environmentally friendly removal technologies given the growing accumulation of microplastics across diverse ecosystems.
Nano-based remediation strategies for micro and nanoplastic pollution
This review covers how nanomaterial-based technologies can be used to remove microplastics from the environment, including methods using magnetic nanoparticles, photocatalysts, and membrane filters. While current physical, chemical, and biological removal methods each have limitations, nanomaterials can enhance their effectiveness by targeting smaller plastic particles that traditional methods miss. Better removal technologies could ultimately reduce human exposure to microplastics in drinking water and food.
Nanoparticle-Based Bioremediation Approach for Plastics and Microplastics
This review explores how nanoparticle-enhanced bioremediation approaches can help address plastic and microplastic pollution. Researchers found that combining biological degradation by bacteria and fungi with engineered nanoparticles can improve the efficiency of breaking down various plastic polymers. The study suggests that these hybrid bioremediation strategies offer a promising eco-friendly pathway for mitigating plastic contamination in the environment.
A review on the role of nanotechnological interventions in sequestration, mitigation and value-added product conversion of micro-/nanoplastics
This review examines how nanotechnology-based approaches can be used to capture, break down, or convert microplastics and nanoplastics into useful products. The buildup of these tiny plastic particles in water environments has become a global health and environmental concern. The review highlights promising technologies that could help clean up microplastic pollution and reduce human exposure.
Unlocking the potential of nanobiohybrids to combat environmental pollution
This review examines how nanobiohybrids — combinations of nanomaterials with biological components — could be used to clean up environmental pollutants, including plastics. The chapter highlights emerging nanotechnology-based bioremediation strategies as sustainable alternatives to conventional pollution management. While not focused on microplastic toxicology, it is relevant to the broader challenge of removing plastic contamination from the environment.
Removal of microplastics in water: Technology progress and green strategies
Researchers reviewed existing technologies for removing microplastics from water, including filtration, magnetic separation, chemical coagulation, and biodegradation. Each method has significant trade-offs — filtration is costly, chemical approaches risk secondary pollution, and biological methods are slow — pointing to the need for integrated, environmentally friendly strategies that combine multiple approaches.
Nanomaterials for Microplastic Removal from Wastewater: Current State of the Art Nanomaterials and Future Prospects
This review surveys recent advances in using nanomaterials to remove microplastics and nanoplastics from wastewater, since conventional treatment plants struggle to capture these tiny particles. Researchers evaluate different nanomaterial approaches including magnetic nanoparticles, photocatalysts, and membrane technologies. The study identifies promising strategies but notes that challenges around scalability, cost, and potential environmental risks of the nanomaterials themselves still need to be addressed.
Review of Techniques for the Detection, Removal, and Transformation of Environmental Microplastics and Nanoplastics
This review covers the latest methods for finding and removing microplastics from the environment, from microscope-based detection to chemical and biological cleanup approaches. Physical methods like filtration and magnetic separation can capture particles, while chemical techniques can actually break plastics down, and biological methods use living organisms to degrade them. The authors also highlight the promising possibility of converting captured microplastics into useful chemicals.
Sustainable coagulative removal of microplastic from aquatic systems: recent progress and outlook
This review examines how natural coagulants from plants, animals, and microbes can be used to remove microplastics from water as a greener alternative to conventional chemical treatments. These bio-based coagulants, especially when combined with nanotechnology, show promising removal rates while avoiding the toxic residues left by traditional chemical approaches.
Challenges and opportunities in bioremediation of micro-nano plastics: A review.
This review examines biological approaches to removing micro- and nanoplastics from the environment, focusing on microbial degradation and bioremediation strategies. While bioremediation holds promise, challenges remain in identifying microbes capable of degrading common plastic types and scaling these processes for practical environmental cleanup.
Application of Nanomaterials in the Degradation of Micro and Nano Plastics
This review examined the application of nanomaterials for degrading micro- and nanoplastics, covering photocatalytic, oxidative, and biological nanomaterial approaches and evaluating their efficiency and scalability for plastic pollution remediation.
Biodegradable Nanomaterials For Removal Of Microplastics Removal In Aquatic Ecosystems
This study explores the potential of biodegradable nanomaterials made from natural polymers like chitosan, cellulose, and lignin to remove microplastics from water. These materials have high surface areas and can be engineered to selectively attract and capture plastic particles through surface interactions. The approach offers a greener alternative to conventional filtration and chemical treatment methods, which are often energy-intensive and can create secondary pollution.
Nanomaterials for the remediation of microplastics in wastewater
This review evaluates how engineered nanomaterials can be used to capture and break down microplastics in wastewater, highlighting approaches based on metal oxide nanoparticles, carbon-based materials, and magnetic composites. Researchers found that these nanomaterials offer high surface area and reactivity advantages over conventional treatment methods. The study identifies scalability, cost, and potential secondary pollution from the nanomaterials themselves as key challenges to address before widespread adoption.
Microplastic removal from wastewater through biopolymer and nanocellulose-based green technologies
Biopolymer-based coagulation and flocculation agents were shown to effectively remove microplastics from wastewater, offering a more sustainable alternative to synthetic chemical flocculants. The approach supports eco-friendly microplastic treatment that avoids adding further chemical pollutants to effluents.
Eco-Solutions to Microplastic Pollution: Advances in Bioremediation Technologies
This review surveys bioremediation technologies, including microbial and plant-based approaches, as potential solutions for removing microplastics from the environment. Researchers highlight promising organisms and enzymatic pathways while noting that practical, scalable applications remain in early development.
A Review of Materials for the Removal of Micro- and Nanoplastics from Different Environments
This review evaluates methods for removing microplastics and nanoplastics from water, soil, and air, finding that traditional approaches like filtration work for larger particles but struggle with nanoscale plastics. Newer technologies like magnetic nanoparticles and photocatalysis show promise, but challenges remain in making these solutions affordable and scalable for real-world cleanup.
The power of green: Harnessing phytoremediation to combat micro/nanoplastics
This review explores how plants and plant-based systems can be used to capture and remove micro- and nanoplastics from contaminated soil and water environments. Researchers found that certain plant species can absorb, trap, or break down plastic particles through their root systems and associated microorganisms. The study suggests that phytoremediation, or using plants to clean up pollution, could become a scalable and environmentally friendly strategy for tackling plastic contamination.
Nanotechnology for the Remediation of Plastic Wastes
This review examines nanotechnology-based approaches for remediation of plastic waste, covering methods to address the growing environmental threat posed by microplastics and nanoplastics as persistent pollutants derived from degrading larger plastic debris.
Bioengineering Solutions for Microplastic Pollution
This review evaluates bioengineering approaches to remove microplastics from the environment, including using microorganisms, plants, and engineered biological systems to break down or sequester plastic particles. While current biological methods are promising, the review identifies key limitations — including the challenge of targeting very small particles — that must be overcome for practical environmental cleanup.
Bioremediation of Microplastics by Microorganisms: Trends, Challenges, and Perspectives
This review examines how microorganisms can be used to break down microplastic pollution in water and soil through bioremediation, a process considered more environmentally friendly than chemical alternatives. Researchers summarized the various microbial mechanisms involved, including enzymatic degradation and biofilm formation on plastic surfaces. While the approach shows promise as a green solution, the study notes that significant challenges remain in scaling these methods for real-world environmental cleanup.