基于生物催化的生物友好微/纳米马达:从自然环境到生物环境。

Ziyi Guo, Jian Liu, Da-Wei Wang, Jiangtao Xu, Kang Liang
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引用次数: 6

摘要

微/纳米马达(MNMs)是一种微小的机动物体,可以在适当的能量来源的影响下在复杂的流体环境中自主导航。内能驱动的纳米材料是由一定的反应材料组成的,这些反应材料能够将来自周围环境的化学能转化为动能。近年来智能纳米材料设计和加工的进展,使得内能驱动的纳米材料具有不同的几何设计和多种运动机制,在从环境水到复杂体液的各种环境中都具有显著的运动速度。在不同的设计原则中,基于生物催化的MNM系统具有生物友好型组件、高效的能量转换和温和的工作条件,显示出走出概念验证阶段的潜力,可以解决许多现实生活中的环境和生物技术挑战。纳米材料的生物亲和性不仅应考虑到体内给药,还应考虑到环境修复和化学传感,即只产生环境友好的中间体和降解产物。本文综述了以生物催化为主要驱动力的生物友好型纳米材料设计的最新进展,以及在生物技术和环境技术方面的实际应用。
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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Biofriendly micro/nanomotors operating on biocatalysis: from natural to biological environments.

Micro/nanomotors (MNMs) are tiny motorized objects that can autonomously navigate in complex fluidic environments under the influence of an appropriate source of energy. Internal energy driven MNMs are composed of certain reactive materials that are capable of converting chemical energy from the surroundings into kinetic energy. Recent advances in smart nanomaterials design and processing have endowed the internal energy driven MNMs with different geometrical designs and various mechanisms of locomotion, with remarkable travelling speed in diverse environments ranging from environmental water to complex body fluids. Among the different design principals, MNM systems that operate from biocatalysis possess biofriendly components, efficient energy conversion, and mild working condition, exhibiting a potential of stepping out of the proof-of-concept phase for addressing many real-life environmental and biotechnological challenges. The biofriendliness of MNMs should not only be considered for in vivo drug delivery but also for environmental remediation and chemical sensing that only environmentally friendly intermediates and degraded products are generated. This review aims to provide an overview of the recent advances in biofriendly MNM design using biocatalysis as the predominant driving force, towards practical applications in biotechnology and environmental technology.

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来源期刊
CiteScore
1.30
自引率
0.00%
发文量
117
期刊最新文献
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