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20 resultsShowing papers similar to Advanced biotechnological tools towards achieving United Nations Sustainable Development Goals (UNSDGs) for mitigation of microplastics from environments: a review
ClearAdvances 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.
The power of synthetic biology for bioproduction, remediation and pollution control
Researchers review how synthetic biology — engineering living organisms to perform new tasks — can help meet UN sustainability goals by creating eco-friendly products and cleaner production processes, offering new tools to tackle pollution and reduce industrial waste.
Biology in the 21st-Century: Transformation in biology science and education in supporting the sustainable development goals
This literature review examines how "New Biology" - the integration of biology with data science, engineering, and sustainability science - can contribute to achieving multiple UN Sustainable Development Goals including zero hunger, clean water, and good health. The study is relevant to microplastics research as it highlights how interdisciplinary biological sciences are increasingly needed to address environmental pollution and its health consequences.
Современное состояние и тенденции в экологической биотехнологии
This review examines the current state and trends in environmental biotechnology for achieving sustainable development goals, covering biotechnological approaches for remediating soil, water, and air from persistent and hazardous pollutants, with a dedicated chapter on the utilization and remediation of aquatic and terrestrial ecosystems contaminated with synthetic materials including microplastics.
Omics Strategies Targeting Microbes with Microplastic Detection and Biodegradation Properties
This review examines how omics approaches — genomics, proteomics, and metabolomics — are being applied to identify and engineer microorganisms capable of detecting and degrading microplastics. The authors map progress in plastic-degrading microbial pathways and discuss how synthetic biology could accelerate the development of bioremediation solutions.
Emerging Frontiers in Environmental Biotechnology
This chapter examines how biotechnology can address microplastic pollution generated by industrialization, reviewing bio-based degradation pathways, nanobiotechnology applications, and the role of engineered organisms in reducing plastic use and waste. The authors assess the future potential of environmental biotechnology as a sustainable tool for managing hazardous microplastic contamination across industries.
Biotechnological advancements in microplastics degradation in drinking water: Current insights and Future perspectives
This review examines the growing concern of microplastics in drinking water and explores biotechnological approaches for breaking them down, including methods from metagenomics and synthetic biology. Researchers note that microplastics have been detected in tap water and various human samples, raising questions about long-term health effects. The study highlights that the wide variety of microplastic sizes and shapes makes detection and removal from liquid water samples particularly challenging.
Bioremediation of microplastic pollution: A systematic review on mechanism, analytical methods, innovations, and omics approaches
Researchers systematically reviewed how bacteria, fungi, and algae can break down microplastics through enzymes and biofilms, and how cutting-edge tools like genomics and genetically engineered microbes are improving biodegradation efficiency. While microbial bioremediation is a promising sustainable approach to microplastic pollution, challenges around scalability and varying degradation rates in real environments still need to be overcome.
Environmental impact and mitigation of micro(nano)plastics pollution using green catalytic tools and green analytical methods
Researchers reviewed the growing problem of microplastics and nanoplastics in the environment, then assessed enzyme-based strategies for breaking them down, finding that enzymes specifically targeting plastic polymer structures offer a promising, sustainable approach to degradation, especially when stabilized on nanomaterials to extend their activity.
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.
Emerging threat of microplastics across environmental matrices encompassing sources ecotoxicological effects and management strategies within the framework of Sustainable Development Goals (SDGs)
This review synthesizes current knowledge on microplastic sources, environmental distribution, and ecotoxicological impacts across various environmental matrices, framed within the UN Sustainable Development Goals. The study highlights how microplastics accumulate across ecosystems and affect organisms at all trophic levels through ingestion and chemical exposure, while identifying management strategies aligned with global sustainability targets.
Some insights on traditional and novel approaches in microbial biotechnology that contribute to the United Nations Sustainable Development Goals
This editorial highlights diverse ways microbial biotechnology contributes to sustainable development goals, discussing both traditional and novel approaches in areas including pollution remediation, food security, and resource recovery.
Biotechnological interventions for monitoring and mitigating microplastic pollution and development of alternatives to single‐use plastics
This review summarizes existing research on biotechnological tools for detecting, monitoring, and cleaning up microplastic pollution, as well as developing bio-based alternatives to single-use plastics. Methods range from satellite imagery and biosensors for detection to bacterial and enzymatic approaches for breaking down plastics. The authors highlight that while promising biological solutions exist, scaling them up to address the vast scope of global microplastic contamination remains a significant challenge.
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.
Emerging biotechnological and eco-remediation strategies for the biodegradation and removal of micro/nanoplastics from the environment: A comprehensive review
Researchers reviewed emerging biotechnological and eco-remediation strategies for removing micro- and nanoplastics from the environment, synthesizing advances in synthetic microbial consortia, enzyme-mediated depolymerization, phytoremediation, and green nanomaterials while highlighting key analytical and field-implementation challenges.
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.
Study of Advanced Techniques for Inquisition, Segregation and Removal of Microplastics from Water Streams: Current Insights and Future Directions
This review surveys the full toolkit of methods used to detect, separate, and remove microplastics from water and wastewater, covering spectroscopic, microscopic, and chromatographic detection alongside physical, chemical, and biological removal strategies. It highlights that no single approach is sufficient and that combining methods — including emerging microfluidic and enzymatic techniques — will be necessary to effectively tackle microplastic contamination in water systems.
Genetic Enhancement of Plastic Degrading Bacteria: The Way to a Sustainable and Healthy Environment
Researchers review how genetic engineering of plastic-degrading bacteria could accelerate the biological breakdown of plastic waste, highlighting promising enzymes and metabolic pathways. Engineering microbes with enhanced plastic-digesting capabilities could become an important tool for reducing the global accumulation of microplastics in the environment.
The plastic and microplastic waste menace and bacterial biodegradation for sustainable environmental clean-up a review
This review examined bacterial biodegradation of plastic and microplastic waste, covering key microbial species, enzymatic mechanisms, and biotechnological approaches being developed for sustainable environmental cleanup of plastic pollution.
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.