Nanozymes with bioorthogonal reaction for intelligence nanorobots.

Si Sun, Xinzhu Chen, Jing Chen, Junying Wang, Xiao-Dong Zhang
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引用次数: 0

Abstract

Bioorthogonal reactions have attained great interest and achievements in various fields since its first appearance in 2003. Compared to traditional chemical reactions, bioorthogonal chemical reactions mediated by transition metals catalysts can occur under physiological conditions in the living system without interfering with or damaging other biochemical events happening simultaneously. The idea of using nanomachines to perform precise and specific tasks in living systems is regarded as the frontier in nanomedicine. Bioorthogonal chemical reactions and nanozymes have provided new potential and strategies for nanomachines used in biomedical fields such as drug release, imaging, and bioengineering. Nanomachines, also called as intelligence nanorobots, based on nanozymes with bioorthogonal reactions show better biocompatibility and water solubility in living systems and perform controlled and adjustable stimuli-triggered response regarding to different physiological environments. In this review, we review the definition and development of bioorthogonal chemical reactions and describe the basic principle of bioorthogonal nanozymes fabrication. We also review several controlled and adjustable stimuli-triggered intelligence nanorobots and their potential in therapeutic and engineered applications. Furthermore, we summarize the challenges in the use of intelligence nanorobots based on nanozymes with bioorthogonal chemical reactions and propose promising vision in smart nanodevices along this appealing avenue of research.

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智能纳米机器人的生物正交反应纳米酶。
生物正交反应自2003年首次出现以来,在各个领域获得了极大的关注和成就。与传统化学反应相比,过渡金属催化剂介导的生物正交化学反应可以在生物系统的生理条件下进行,而不会干扰或破坏同时发生的其他生化事件。利用纳米机器在生命系统中执行精确和特定任务的想法被认为是纳米医学的前沿。生物正交化学反应和纳米酶为纳米机器在药物释放、成像和生物工程等生物医学领域的应用提供了新的潜力和策略。纳米机器也被称为智能纳米机器人,它基于纳米酶的生物正交反应,在生命系统中具有更好的生物相容性和水溶性,并对不同的生理环境进行可控和可调节的刺激触发反应。本文综述了生物正交化学反应的定义和发展,并介绍了制备生物正交纳米酶的基本原理。我们还回顾了几种可控和可调节的刺激触发智能纳米机器人及其在治疗和工程应用中的潜力。此外,我们总结了使用基于纳米酶与生物正交化学反应的智能纳米机器人所面临的挑战,并提出了沿着这一诱人的研究途径在智能纳米器件方面的前景。
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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CiteScore
1.30
自引率
0.00%
发文量
117
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