Abstract
Bisphenol A (BPA) is a known endocrine disruptor that poses concerning environmental and human-health related issues and ecological risks. It has been largely used as an intermediate in the manufacture of epoxy resins and polycarbonate plastics. Traces of BPA can reach into the environment through inadequate or inefficient removal during wastewater treatment, uncontrolled landfill leachates, and leaching out from the discarded BPA-based materials. Several physicochemical treatment methods including adsorption, Fenton, ozonation, electrochemical and photochemical degradation, and membrane filtration, have been applied for BPA elimination. However, these methods are not adequate for large-scale treatment due to some inherent limitations. Benefiting from high catalytic efficiency and specificity, enzyme-based bio-catalytic degradation strategies are considered quite meaningful alternative for efficient and effective BPA removal from different routes. Among various oxidoreductases, i.e., laccases exhibited a superior potential for the remediation of BPA-containing wastewater. Enzymatic oxidation of BPA can be boosted by using various natural or synthetic redox mediators. Immobilized enzymes can expand their applicability to continuous bioprocessing and facilitates process intensification. Therefore, optimized formulations of insolubilized biocatalysts are of strategic interest in the environmental biotechnology. In this review, recent research studies dealing with BPA removal by the laccase-catalyzed system are presented. At first, the presence of BPA in the ecosystem, sources, exposure, and its impact on the living organisms and human beings is summarized. Then, we highlighted the use of crude as well as immobilized laccases for the degradation of BPA. In addition to toxicity and estrogenicity removal studies, the unresolved challenges, concluding remarks, and possible future direction is proposed in this important research area. It is palpable from the literature reviewed that free as well as immobilized forms of laccases have displayed noteworthy potential for BPA removal from wastewater.
Highlights
Endocrine disrupting chemicals (EDCs) have recently drawn scientific and public attention due to evident environmental issues
Barceló) of its widespread application as monomers in the manufacture of epoxy resins and polycarbonate plastic (Fig. 1). These epoxy resins are utilized in preparing polycarbonate baby feeding bottles and epoxy food-Can coatings (Dekant and Völkel, 2008). It has been categorized as an EDCs by the US Environmental Protection Agency (EPA) because it interferes with production, secretion, transport, mechanism of action or removal of natural hormones associated with the homeostasis, behavior or reproduction in living organisms
This review summarizes the current progress regarding the application of soluble as well as immobilized laccase enzymes from different microbial source for the biotransformation and removal of Bisphenol A (BPA) from the aqueous media
Summary
Endocrine disrupting chemicals (EDCs) have recently drawn scientific and public attention due to evident environmental issues These compounds disrupt hormonal activities and adversely affect human health and aquatic organisms by disrupting growth, development, and reproduction. After a description of the potential source, occurrence, and associated detrimental effects on the ecosystem/human health, the use of free and immobilized laccase-based biocatalytic systems for the degradation and detoxification of BPA is highlighted. WWTPs are conceived as one of the leading secondary routes of BPA pollution because of its inadequate degradation or elimination by physicochemical and biological treatment methods It can enter industrial and municipal wastewater through direct discharge to sewers and stormwater run-off (Mohapatra et al, 2010).
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