用于分析单个分子的基于聚合物的纳米传感器芯片的流体操作。

IF 2.8 Q2 MECHANICS
Flow (Cambridge, England) Pub Date : 2022-01-01 Epub Date: 2022-06-27 DOI:10.1017/flo.2022.8
Swarnagowri Vaidyanathan, Sachindra Gamage, Kavya Dathathreya, Renee Kryk, Anishkumar Manoharan, Zheng Zhao, Lulu Zhang, Junseo Choi, Daniel Park, Sunggook Park, Steven A Soper
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引用次数: 0

摘要

大多数医学诊断测试都很昂贵,集中实验室的周转时间很慢,并且需要高度专业化的设备和经验丰富的技术人员来进行分析。为了促进在护理点实现精准医疗,我们开发了一种具有高表面积柱阵列的混合规模纳米传感器芯片,可以在其中进行固相反应,以检测和识别在患病患者中发现的核酸靶点。形成的产物可以使用聚合物纳米流体通道来识别和检测。为了指导该平台的交付,我们通过研究柱阵列负载、流体动力学和电动流等参数,讨论了用于指导设计的设备和模拟(COMSOL)的各个组件的操作。讨论了纳米传感器的制造,该制造是使用硅(Si)母版进行的,该母版通过聚焦离子束铣削和光刻与深反应离子蚀刻相结合进行图案化。通过热纳米压印光刻将混合规模的图案转移到热塑性塑料中,这有助于纳米传感器芯片的制造,使其适用于体外诊断。COMSOL的结果通过实验验证了使用罗丹明B作为荧光示踪剂的流体动力学流动和使用单个荧光标记的寡核苷酸(单链DNA,ssDNA)的电动流动。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Fluidic operation of a polymer-based nanosensor chip for analysing single molecules.

Fluidic operation of a polymer-based nanosensor chip for analysing single molecules.

Fluidic operation of a polymer-based nanosensor chip for analysing single molecules.

Fluidic operation of a polymer-based nanosensor chip for analysing single molecules.

Most medical diagnostic tests are expensive, involve slow turnaround times from centralized laboratories and require highly specialized equipment with seasoned technicians to carry out the assay. To facilitate realization of precision medicine at the point of care, we have developed a mixed-scale nanosensor chip featuring high surface area pillar arrays where solid-phase reactions can be performed to detect and identify nucleic acid targets found in diseased patients. Products formed can be identified and detected using a polymer nanofluidic channel. To guide delivery of this platform, we discuss the operation of various components of the device and simulations (COMSOL) used to guide the design by investigating parameters such as pillar array loading, and hydrodynamic and electrokinetic flows. The fabrication of the nanosensor is discussed, which was performed using a silicon (Si) master patterned with a combination of focused ion beam milling and photolithography with deep reactive ion etching. The mixed-scale patterns were transferred into a thermoplastic via thermal nanoimprint lithography, which facilitated fabrication of the nanosensor chip making it appropriate for in vitro diagnostics. The results from COMSOL were experimentally verified for hydrodynamic flow using Rhodamine B as a fluorescent tracer and electrokinetic flow using single fluorescently labelled oligonucleotides (single-stranded DNAs, ssDNAs).

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CiteScore
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