Nanotechnology-Enabled PCR with Tunable Energy Dynamics

IF 8.5 Q1 CHEMISTRY, MULTIDISCIPLINARY JACS Au Pub Date : 2024-08-30 DOI:10.1021/jacsau.4c0057010.1021/jacsau.4c00570
Xinmin Zhao, Hongzhen Peng, Jun Hu, Lihua Wang* and Feng Zhang*, 
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Abstract

This Perspective elucidates the transformative impacts of advanced nanotechnology and dynamic energy systems on the polymer chain reaction (PCR), a cornerstone technique in biomedical research and diagnostic applications. Since its invention, the optimization of PCR─specifically its efficiency, specificity, cycling rate, and detection sensitivity─has been a focal point of scientific exploration. Our analysis spans the modulation of PCR from both material and energetic perspectives, emphasizing the intricate interplay between PCR components and externally added entities such as molecules, nanoparticles (NPs), and optical microcavities. We begin with a foundational overview of PCR, detailing the basic principles of PCR modulation through molecular additives to highlight material-level interactions. Then, we delve into how NPs, with their diverse material and surface properties, influence PCR through interface interactions and hydrothermal conduction, drawing parallels to molecular behaviors. Additionally, this Perspective ventures into the energetic regulation of PCR, examining the roles of electromagnetic radiation and optical resonators. We underscore the advanced capabilities of optical technologies in PCR regulation, characterized by their ultrafast, residue-free, and noninvasive nature, alongside label-free detection methods. Notably, optical resonators present a pioneering approach to control PCR processes even in the absence of light, targeting the often-overlooked water component in PCR. By integrating discussions on photocaging and vibrational strong coupling, this review presents innovative methods for the precise regulation of PCR processes, envisioning a new era of PCR technology that enhances both research and clinical diagnostics. The synergy between nanotechnological enhancements and energy dynamics not only enriches our understanding of PCR but also opens new avenues for developing rapid, accurate, and efficient PCR systems. We hope that this Perspective will inspire further innovations in PCR technology and guide the development of next-generation clinical detection instruments.

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可调能量动态的纳米技术 PCR
本视角阐明了先进纳米技术和动态能源系统对聚合物链反应(PCR)的变革性影响,PCR 是生物医学研究和诊断应用中的一项基石技术。自 PCR 发明以来,对其进行优化(特别是其效率、特异性、循环速率和检测灵敏度)一直是科学探索的焦点。我们从材料和能量两个角度对 PCR 的调控进行了分析,强调了 PCR 成分与分子、纳米粒子 (NP) 和光学微腔等外部添加实体之间错综复杂的相互作用。我们从 PCR 的基础概述开始,详细介绍了通过分子添加剂调制 PCR 的基本原理,以突出材料层面的相互作用。然后,我们将深入探讨具有不同材料和表面特性的 NPs 如何通过界面相互作用和水热传导影响 PCR,并将其与分子行为进行比较。此外,本视角还探讨了 PCR 的能量调节,研究了电磁辐射和光学谐振器的作用。我们强调了光学技术在 PCR 调控中的先进功能,其特点是超快、无残留、非侵入性以及无标记检测方法。值得注意的是,光学谐振器针对 PCR 中经常被忽视的水成分,提出了一种即使在无光条件下也能控制 PCR 过程的开创性方法。本综述综合讨论了光致变色和振动强耦合,提出了精确调控 PCR 过程的创新方法,展望了 PCR 技术的新时代,从而提高研究和临床诊断水平。纳米技术增强与能量动力学之间的协同作用不仅丰富了我们对 PCR 的理解,还为开发快速、准确、高效的 PCR 系统开辟了新途径。我们希望本《视角》能激发 PCR 技术的进一步创新,并为下一代临床检测仪器的开发提供指导。
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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10 weeks
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