Dynamic DNA nanomachines for amplification imaging of diseased cells based on stimuli-responsive mechanism

Jingting Wu, Wenqing Lin, Zai-Sheng Wu
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引用次数: 2

Abstract

As a basic functional unit, living cell with sophisticated structures play an indispensable role in life activities. Since the abnormality of important molecules inside cells is closely related to diseases, the dynamic analysis and spatio-temporal monitoring of specific molecules in living cells can provide precious information for the diagnosis and treatment of diseases. More recently, DNA has not only been recognized as the carrier of genetic information, but has also used as a robust building block for the assembly of multitudinous nanoscale structures due to the intrinsic advantages of high programmability of classic Watson–Crick base-pairing rule. Intensive study promotes the rapid progress of nanotechnology in various fields, such as bioimaging, diagnosis, and therapeutics. Among numerous well-defined DNA nanomaterials, DNA nanomachines have been widely exploited in cell imaging owing to their desirable ability to achieve high-resolution temporal and spatial images in response to endogenous or exogenous stimuli. In brief, elaborate DNA nanomachines can undergo structural changes upon the stimuli of target analytes or environmental factors, resulting in rapid increase or reduction of output signals and thereby indirectly reflecting the expression level of targets. DNA nanomachines with high sensitivity and specificity contribute to the recognition of diseased tissues. In this review, we introduce the basic assembly modules of DNA nanomachines and summarize the recent advances in dynamic DNA nanomachines for diseased-cell imaging. Finally, the current challenges and future directions of DNA nanomachines for bioimaging are discussed.

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基于刺激反应机制的病变细胞扩增成像的动态DNA纳米机
细胞作为一个基本的功能单元,结构复杂,在生命活动中发挥着不可或缺的作用。由于细胞内重要分子的异常与疾病密切相关,对活细胞中特定分子的动态分析和时空监测可以为疾病的诊断和治疗提供宝贵的信息。最近,DNA不仅被认为是遗传信息的载体,而且由于经典Watson–Crick碱基配对规则的高可编程性的内在优势,它还被用作组装众多纳米级结构的强大构建块。深入的研究促进了纳米技术在生物成像、诊断和治疗等各个领域的快速发展。在众多定义明确的DNA纳米材料中,DNA纳米机器由于其响应内源性或外源性刺激而获得高分辨率时间和空间图像的理想能力,已被广泛用于细胞成像。简言之,精细的DNA纳米机器可以在目标分析物或环境因素的刺激下发生结构变化,导致输出信号的快速增加或减少,从而间接反映目标的表达水平。具有高灵敏度和特异性的DNA纳米机器有助于识别病变组织。在这篇综述中,我们介绍了DNA纳米机器的基本组装模块,并总结了动态DNA纳米机器用于病变细胞成像的最新进展。最后,讨论了DNA纳米机器用于生物成像的当前挑战和未来方向。
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