Multidisciplinary approaches for enzyme biocatalysis in pharmaceuticals: protein engineering, computational biology, and nanoarchitectonics

EES catalysis Pub Date : 2023-10-28 DOI:10.1039/D3EY00239J
Suhyeon Kim, Seongmin Ga, Hayeon Bae, Ronald Sluyter, Konstantin Konstantinov, Lok Kumar Shrestha, Yong Ho Kim, Jung Ho Kim and Katsuhiko Ariga
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Abstract

Enzyme biocatalysis is reshaping pharmaceutical synthesis, offering sustainable and efficient pathways for drug discovery and production. This paradigm shift towards eco-friendly methodologies addresses concerns inherent in traditional chemical synthesis. Enzymes, celebrated for their precision and adaptability to mild conditions, are poised as ideal candidates for pharmaceutical applications. Their versatility facilitates the synthesis of diverse pharmaceutical compounds, ensuring precise drug design and minimizing environmental impact. The integration of multidisciplinary approaches, including protein engineering, computational biology, and nanoarchitectonics, holds the potential to propel enzyme biocatalysis even further. Protein engineering utilizes directed evolution and rational design to customize enzymes, enhancing their stability and efficacy. Computational biology aids in deciphering enzymatic mechanisms, while nanoarchitectonics introduces innovative enzyme integration strategies into continuous flow systems. This comprehensive review explores how these multidisciplinary approaches can revolutionize pharmaceutical research and production. The synergy among these disciplines promises to expedite pharmaceutical processes, promote sustainability, optimize efficiency, and elevate precision—aligning perfectly with the evolving requirements of the pharmaceutical industry.

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制药中的酶生物催化多学科方法:蛋白质工程学、计算生物学和纳米结构学
酶生物催化正在重塑药物合成,为药物发现和生产提供可持续的高效途径。这种向生态友好型方法转变的模式解决了传统化学合成中固有的问题。酶以其精确性和对温和条件的适应性而著称,是制药应用的理想候选者。酶的多功能性有助于合成各种药物化合物,确保药物设计的精确性,并最大限度地减少对环境的影响。蛋白质工程、计算生物学和纳米结构学等多学科方法的整合,有望进一步推动酶生物催化。蛋白质工程利用定向进化和合理设计来定制酶,从而提高酶的稳定性和功效。计算生物学有助于破译酶的机理,而纳米建筑学则将创新的酶整合策略引入到连续流动系统中。本综述探讨了这些多学科方法如何彻底改变制药研究和生产。这些学科之间的协同作用有望加快制药过程、促进可持续发展、优化效率并提高精确度--完全符合制药行业不断发展的要求。
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