Controlling Matter at the Molecular Scale with DNA Circuits.

IF 12.8 1区工程技术 Q1 ENGINEERING, BIOMEDICAL Annual Review of Biomedical Engineering Pub Date : 2019-06-04 DOI:10.1146/annurev-bioeng-060418-052357

Dominic Scalise, Rebecca Schulman

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引用次数: 38

Abstract

In recent years, a diverse set of mechanisms have been developed that allow DNA strands with specific sequences to sense information in their environment and to control material assembly, disassembly, and reconfiguration. These sequences could serve as the inputs and outputs for DNA computing circuits, enabling DNA circuits to act as chemical information processors to program complex behavior in chemical and material systems. This review describes processes that can be sensed and controlled within such a paradigm. Specifically, there are interfaces that can release strands of DNA in response to chemical signals, wavelengths of light, pH, or electrical signals, as well as DNA strands that can direct the self-assembly and dynamic reconfiguration of DNA nanostructures, regulate particle assemblies, control encapsulation, and manipulate materials including DNA crystals, hydrogels, and vesicles. These interfaces have the potential to enable chemical circuits to exert algorithmic control over responsive materials, which may ultimately lead to the development of materials that grow, heal, and interact dynamically with their environments.

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用DNA电路在分子尺度上控制物质。

近年来，研究人员开发了一套不同的机制，使具有特定序列的DNA链能够感知环境中的信息，并控制物质的组装、拆卸和重新配置。这些序列可以作为DNA计算电路的输入和输出，使DNA电路能够作为化学信息处理器，对化学和材料系统中的复杂行为进行编程。这篇综述描述了在这样一个范例中可以被感知和控制的过程。具体来说，有一些界面可以根据化学信号、光波长、pH值或电信号释放DNA链，还有一些DNA链可以指导DNA纳米结构的自组装和动态重构，调节粒子组装，控制封装，操纵包括DNA晶体、水凝胶和囊泡在内的材料。这些界面有可能使化学电路对响应材料施加算法控制，这可能最终导致材料的发展，这些材料可以生长，愈合，并与环境动态互动。

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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来源期刊

Annual Review of Biomedical Engineering 工程技术-工程：生物医学

CiteScore

18.80

自引率

0.00%

发文量

期刊介绍： Since 1999, the Annual Review of Biomedical Engineering has been capturing major advancements in the expansive realm of biomedical engineering. Encompassing biomechanics, biomaterials, computational genomics and proteomics, tissue engineering, biomonitoring, healthcare engineering, drug delivery, bioelectrical engineering, biochemical engineering, and biomedical imaging, the journal remains a vital resource. The current volume has transitioned from gated to open access through Annual Reviews' Subscribe to Open program, with all articles published under a CC BY license.