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Sustainable environmental remediation via biomimetic multifunctional lignocellulosic nano-framework

Jinghao Li, Xiaohan Li, Yabin Da, Jiali Yu, Bin Long, Peng Zhang, Christopher Bakker, Bruce A. McCarl, Joshua S. Yuan, Susie Y. Dai

2022Nature Communications124 citationsDOIOpen Access PDF

Abstract

Chemical pollution threatens human health and ecosystem sustainability. Persistent organic pollutants (POPs) like per- and polyfluoroalkyl substances (PFAS) are expensive to clean up once emitted. Innovative and synergistic strategies are urgently needed, yet process integration and cost-effectiveness remain challenging. An in-situ PFAS remediation system is developed to employ a plant-derived biomimetic nano-framework to achieve highly efficient adsorption and subsequent fungal biotransformation synergistically. The multiple component framework is presented as Renewable Artificial Plant for In-situ Microbial Environmental Remediation (RAPIMER). RAPIMER exhibits high adsorption capacity for the PFAS compounds and diverse adsorption capability toward co-contaminants. Subsequently, RAPIMER provides the substrates and contaminants for in situ bioremediation via fungus Irpex lacteus and promotes PFAS detoxification. RAPIMER arises from cheap lignocellulosic sources, enabling a broader impact on sustainability and a means for low-cost pollutant remediation.

Topics & Concepts

Environmental remediationNano-NanotechnologyEnvironmental scienceBiochemical engineeringMaterials scienceEngineeringEcologyBiologyChemical engineeringContaminationMicroplastics and Plastic PollutionNanoparticles: synthesis and applicationsGraphene and Nanomaterials Applications
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