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61,005 resultsShowing papers similar to Emerging Frontiers in Environmental Biotechnology
ClearMicrobial biotechnology addressing the plastic waste disaster
This review covers how microbial biotechnology can help address plastic pollution, from engineering microorganisms to degrade plastics to developing biodegradable alternatives. Biological approaches to plastic management could help reduce the global accumulation of microplastics.
A concept for the biotechnological minimizing of emerging plastics, micro- and nano-plastics pollutants from the environment: A review.
This review examined biotechnological strategies for remediating plastics, micro-, and nano-plastics from the environment, cataloguing microbial and enzymatic degradation approaches, discussing their mechanistic basis, and proposing an integrated biotechnology framework for minimizing plastic pollution across terrestrial and aquatic systems.
Genetic engineering approach to address microplastic environmental pollution: a review
This review explores how genetic engineering approaches could enhance the ability of microorganisms to biodegrade microplastics and nanoplastics in the environment. Researchers highlight that while wild-type microbes struggle to break down plastics due to their high molecular weight and crystallinity, engineered enzymes and organisms show potential for more effective plastic pollution remediation.
Innovative Approaches to Microplastic and Nano-plastic Biodegradation
This review covers innovative biotechnological approaches to microplastic and nanoplastic biodegradation, examining the origins of these particles from larger plastic waste and intentionally manufactured microbeads. The authors assess promising biological and enzymatic strategies for accelerating breakdown of persistent plastic polymers in environmental and engineered systems.
Microplastic Accumulation and Degradation in Environment via Biotechnological Approaches
This review examines how biotechnological approaches, including genetic engineering, genome editing, and synthetic biology, can enhance microbial degradation of plastics. Researchers found that while microplastics and nanoplastics are now found throughout the environment and even in food and the human body, improved methods for plastic biodegradation could help reduce their production. The study highlights the potential of engineered microorganisms as a strategy for addressing plastic waste accumulation.
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.
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.
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.
Microplastics Pollution and its Remediation
This publication reviews the growing problem of microplastic pollution in the environment and explores biological and technological strategies for remediation, including microbial degradation and engineered solutions. It highlights the urgent need for practical cleanup approaches as microplastics continue to accumulate across ecosystems worldwide.
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.
Advances in microplastic mitigation: current progress and future directions
This review synthesizes recent advances in biotechnology-based approaches to microplastic remediation, including microbial degradation, engineered enzyme systems, and AI-driven monitoring. Researchers found that while promising enzymes and engineered biofilm systems have been demonstrated in the lab, translating these solutions to diverse polymer types and real-world field applications remains a major challenge. The study proposes a unified roadmap for scaling sustainable biotechnology solutions to address the global microplastic crisis.
Biotechnological Potential for Microplastic Waste
This article reviews how biotechnology — including engineered microbes and enzymes — can be used to break down microplastic waste. As conventional plastic recycling falls short, biological approaches offer a promising complement to reduce the accumulation of microplastics in the environment.
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.
Bioeconomics in solving environmental problems
This paper examines how biotechnology — using living organisms and biological processes — can address environmental problems including pollution cleanup, sustainable energy, and biodegradable materials. Biotechnological approaches such as plastic-degrading microbes are increasingly relevant to solving the microplastic pollution crisis.
Life Sciences and Environmental Challenges: A Biotechnology Perspective
This book examines biotechnology perspectives on life sciences and environmental challenges, covering topics relevant to microplastic pollution, biodegradation, and emerging biotechnological solutions for environmental remediation.
Role of Nanotechnology in Plastic and Microplastic Management
This review examines how nanotechnology can enhance plastic and microplastic degradation, describing how nanomaterials can modify microbial metabolic pathways to improve biodegradation rates and how photocatalytic approaches can break down plastics into low-molecular-weight intermediates suitable for use as chemical feedstocks.
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 minireview on the bioremediative potential of microbial enzymes as solution to emerging microplastic pollution
This mini review explores the potential of microbial enzymes as a sustainable solution for degrading microplastics, discussing recent advances in identifying plastic-degrading enzymes and the challenges remaining for practical bioremediation applications.
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.
Nanobiocatalysts and its Applications: A Review Article
This review covers nanobiocatalysts — enzymes attached to nanostructures — and their applications in biotechnology, including potential uses in breaking down plastic pollution. Nanobiocatalysts offer improved stability and efficiency for industrial enzymes, including those being explored for plastic biodegradation.
Microplastic pollution: Understanding microbial degradation and strategies for pollutant reduction
This review explores how microplastics form, spread through ecosystems, and affect microbial communities, then examines how certain microorganisms can actually break down these plastic particles. Understanding microbial degradation of microplastics could lead to biotechnology solutions that reduce the amount of plastic pollution entering the food chain and ultimately the human body.
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.
[Preface to the special issue: biotechnology of plastic waste degradation and valorization].
This preface introduces a special issue on biotechnology approaches to plastic waste degradation and valorization, covering microbial and enzymatic strategies for breaking down synthetic plastics. Biological plastic degradation could help reduce the environmental persistence of plastics that eventually fragment into microplastics.