Enzyme-loaded nanostructured materials for the degradation of environmental pollutants

IF 6.7 Q1 ENVIRONMENTAL SCIENCES

Current Opinion in Environmental Science and Health Pub Date : 2022-12-01 DOI:10.1016/j.coesh.2022.100400

Mahpara Qamar , Aneela Basharat , Sarmad Ahmad Qamar , Muhammad Bilal , Marcelo Franco , Hafiz M.N. Iqbal

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引用次数: 3

Abstract

Nanomaterials are widely used for enzyme immobilization purposes to impart desired functionality, including superior catalytic features, high stability, high specificity, and recyclability to reduce the cost of the bioprocess. The immobilization technology can stabilize the enzymes structures against chemical and/or environmental damage. The enzyme-loaded nanocarriers could be recovered and processed in another cycle that indicates bioprocess's cost-effectiveness. Combining nanostructured materials with biotechnological processes has provided an efficient platform to design state-of-the-art nanostructures for enzyme loading inducing desired characteristics. This review aimed to summarize different nanomaterials (including silica-based, metal-based, polymer-based, and carbon-based) for their enzyme immobilization potentialities. Furthermore, the applications of these enzyme-loaded nanomaterials in environmental remediation, i.e., the removal of pharmaceutical compounds and textile dyes, have been described in detail.

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载酶纳米结构材料降解环境污染物

纳米材料被广泛用于酶固定化目的，以赋予所需的功能，包括优越的催化特性，高稳定性，高特异性和可回收性，以降低生物过程的成本。固定化技术可以稳定酶的结构，防止化学和/或环境的破坏。负载酶的纳米载体可以在另一个循环中回收和处理，这表明生物工艺的成本效益。将纳米结构材料与生物技术工艺相结合为设计最先进的纳米结构提供了一个有效的平台，用于酶负载诱导所需的特性。本文综述了不同纳米材料(包括硅基、金属基、聚合物基和碳基)的酶固定化潜力。此外，还详细介绍了这些载酶纳米材料在环境修复中的应用，即去除药物化合物和纺织染料。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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