Overcoming the limitations of COVID-19 diagnostics with nanostructures, nucleic acid engineering, and additive manufacturing

IF 12.2 2区 材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY
Nantao Li , Bin Zhao , Robert Stavins , Ana Sol Peinetti , Neha Chauhan , Rashid Bashir , Brian T. Cunningham , William P. King , Yi Lu , Xing Wang , Enrique Valera
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引用次数: 6

Abstract

The COVID-19 pandemic revealed fundamental limitations in the current model for infectious disease diagnosis and serology, based upon complex assay workflows, laboratory-based instrumentation, and expensive materials for managing samples and reagents. The lengthy time delays required to obtain test results, the high cost of gold-standard PCR tests, and poor sensitivity of rapid point-of-care tests contributed directly to society’s inability to efficiently identify COVID-19-positive individuals for quarantine, which in turn continues to impact return to normal activities throughout the economy. Over the past year, enormous resources have been invested to develop more effective rapid tests and laboratory tests with greater throughput, yet the vast majority of engineering and chemistry approaches are merely incremental improvements to existing methods for nucleic acid amplification, lateral flow test strips, and enzymatic amplification assays for protein-based biomarkers. Meanwhile, widespread commercial availability of new test kits continues to be hampered by the cost and time required to develop single-use disposable microfluidic plastic cartridges manufactured by injection molding. Through development of novel technologies for sensitive, selective, rapid, and robust viral detection and more efficient approaches for scalable manufacturing of microfluidic devices, we can be much better prepared for future management of infectious pathogen outbreaks. Here, we describe how photonic metamaterials, graphene nanomaterials, designer DNA nanostructures, and polymers amenable to scalable additive manufacturing are being applied towards overcoming the fundamental limitations of currently dominant COVID-19 diagnostic approaches. In this paper, we review how several distinct classes of nanomaterials and nanochemistry enable simple assay workflows, high sensitivity, inexpensive instrumentation, point-of-care sample-to-answer virus diagnosis, and rapidly scaled manufacturing.

利用纳米结构、核酸工程和增材制造克服新冠肺炎诊断的局限性
COVID-19大流行揭示了当前传染病诊断和血清学模型的根本局限性,该模型基于复杂的分析工作流程、基于实验室的仪器以及用于管理样品和试剂的昂贵材料。获得检测结果所需的长时间延迟、金标准PCR检测的高成本以及快速即时检测的低灵敏度直接导致社会无法有效识别covid -19阳性个体进行隔离,这反过来继续影响整个经济恢复正常活动。在过去的一年里,我们投入了大量的资源来开发更有效的快速检测和更高通量的实验室检测,然而绝大多数的工程和化学方法仅仅是对现有的核酸扩增、侧流试纸和酶扩增检测蛋白质生物标志物的方法的渐进改进。同时,新测试套件的广泛商业可用性继续受到开发一次性微流体塑料盒所需的成本和时间的阻碍,这些盒是通过注射成型制造的。通过开发灵敏、选择性、快速和强大的病毒检测新技术,以及更有效的微流控设备可扩展制造方法,我们可以为未来传染性病原体爆发的管理做好更好的准备。在这里,我们描述了如何应用光子超材料、石墨烯纳米材料、设计DNA纳米结构和适用于可扩展增材制造的聚合物来克服目前占主导地位的COVID-19诊断方法的基本局限性。在本文中,我们回顾了几种不同类别的纳米材料和纳米化学如何实现简单的分析工作流程、高灵敏度、廉价的仪器、即时从样本到答案的病毒诊断和快速规模化生产。
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来源期刊
Current Opinion in Solid State & Materials Science
Current Opinion in Solid State & Materials Science 工程技术-材料科学:综合
CiteScore
21.10
自引率
3.60%
发文量
41
审稿时长
47 days
期刊介绍: Title: Current Opinion in Solid State & Materials Science Journal Overview: Aims to provide a snapshot of the latest research and advances in materials science Publishes six issues per year, each containing reviews covering exciting and developing areas of materials science Each issue comprises 2-3 sections of reviews commissioned by international researchers who are experts in their fields Provides materials scientists with the opportunity to stay informed about current developments in their own and related areas of research Promotes cross-fertilization of ideas across an increasingly interdisciplinary field
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