Advances and feasibility of biocatalytic technologies for dye removal

K. Tang
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Abstract

The expanding dye and dye-related industries have led to the production of large volumes of dye-containing wastewater streams. Without adequate treatment, the wastewater could pollute the environment and give rise to health concerns. Biocatalytic technologies provide a channel of treating the wastewater. These technologies involve immobilizing dye-degrading enzymes particularly laccase and peroxidase, and microorganisms on or in suitable supports to enhance their activities, stability, efficiency, and recyclability. This review provides the latest advances in biocatalytic technologies and their feasibility. Based on this review, laccase has been immobilized on supports comprising PEDOT-PPy-COOH/Pt, nanocellulose from quinoa husks, calcium alginate, delignified spent grain, polymeric membrane, and metal-organic frameworks to treat different dyes with efficiencies ranging from 39% to 100%. Peroxidase has been immobilized on calcium alginate, Fe3O4 nanoparticles, cationic maize starch, and graphene oxide-SiO2 for treatment of various dyes with efficiencies in the range of 40–100%. The dye-degrading ability of azoreductase is often harnessed through immobilization of microbial cells which contain multiple enzymes in them and are frequently able to decolorize more than 90% of the dyes tested. An immobilized azoreductase has been successfully produced but showed lower dye-degrading efficiencies of 18.3–58.3%. The performance of biocatalysts can be affected by multiple factors, making optimization of the operating conditions important. The use of green support materials could reduce the cost of biocatalysts and the associated environmental concerns. A versatile biocatalyst or biocatalyst mixture is beneficial to degrade the complex pollutants in dye-containing wastewater.  
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用于去除染料的生物催化技术的进展和可行性
染料和与染料相关的工业不断扩大,产生了大量含染料的废水。如果不进行适当的处理,这些废水可能会污染环境并引发健康问题。生物催化技术提供了一种处理废水的方法。这些技术涉及将染料降解酶(尤其是漆酶和过氧化物酶)和微生物固定在合适的支撑物上或支撑物中,以提高它们的活性、稳定性、效率和可回收性。本综述介绍了生物催化技术的最新进展及其可行性。根据这篇综述,漆酶已被固定在由 PEDOT-PPy-COOH/Pt、藜壳纳米纤维素、海藻酸钙、脱木质素废谷物、聚合物膜和金属有机框架组成的支持物上,用于处理不同的染料,效率从 39% 到 100% 不等。将过氧化物酶固定在海藻酸钙、Fe3O4 纳米粒子、阳离子玉米淀粉和氧化石墨烯-二氧化硅上处理各种染料的效率在 40-100% 之间。偶氮还原酶的染料脱色能力通常是通过固定微生物细胞来实现的,这些细胞中含有多种酶,通常能够使 90% 以上的受测染料脱色。固定化偶氮还原酶已成功生产,但染料脱色效率较低,仅为 18.3-58.3%。生物催化剂的性能会受到多种因素的影响,因此优化操作条件非常重要。使用绿色支持材料可以降低生物催化剂的成本和相关的环境问题。多功能生物催化剂或生物催化剂混合物有利于降解含染料废水中的复杂污染物。
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