Programmable micro/nano-fluidic based platform for high-throughput and large scale single-molecule analysis

基于可编程微/纳米流体的平台，用于高通量和大规模单分子分析

• 批准号: RGPIN-2016-04943
• 负责人: Ahamed, MohammedJalal
• 金额: $ 1.68万
• 依托单位: University of Windsor
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2019
• 资助国家: 加拿大
• 起止时间: 2019-01-01 至 2020-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=679385
• 关键词: Programmable; micro; nano; fluidic; based

The vision of this research program is to engineer micro/nano-fluidic based incisive technologies that would facilitate our ability to reach and explore rare events in single biomolecular functionalities. Single molecule analysis is a powerful approach that allows unprecedented new details of biomedical information, which are not possible using conventional averaging techniques. It facilities in our understanding of complex biological process (for example diseases like Cancer), where it is necessary to identify the functional characteristics of protein, DNA, RNA at single molecule level extracted from a single cell. A programmable, efficient, disposable, and miniature "smart" system can dramatically improve biological analysis accessible at our point-of-interest. Efficient sample manipulation, isolation, through-put, configurability and large-scale analysis capability are the key for such smart miniaturized lab-chip system. This research program would for the first time innovate "smart" micro/nano-fluidic technologies via synergistically combining 3D fabricated sample manipulator with programmable droplet based microfluidics. 3D feature based sample manipulator can enhance the ability to capture, isolate and translocate single biomolecules. Additionally, programmable microfluidics allows integrating on-chip decision-making capability via real-time sensing and controls. From the engineering and basic science point of view, the research will address a number of fundamental questions including: 3D micro/nano fabrication on glass, transport of bio-molecules through micro/nanometer-size 3D geometries, mechanical behavior of molecules at varying nano-confinement, and biomolecules transport and controls using nano-electrowetting. ***My first objective is to create a 3D fabrication method with high-aspect ratio and high precision manufacturing of micro/nano-features for biomolecule manipulation. 3D features such as modified channel, continuous confinement, post arrays, funnels, and diamonds are used for DNA untangling, linearization and translocation. Conventional fabrication methods are based on dry/wet chemical etching, that has higher roughness, limited aspect ratio and feature quality. In this research, 3D fabrication by using a new method based on thermal shape deformation of glass will be pursued. The second objective of is to integrate programmable fluidics with 3D micro/nano-features. Programmable droplet based flows will be first time combined with continuous confinement nano-fluidics for achieving high-throughput, faster and large scale single molecule analysis. The wide implication of this program offers many attractive applications including health care, disease diagnostics, drug discovery, environmental security, agriculture and basic research.**

这项研究计划的愿景是设计基于微/纳米流体的精密技术，这将有助于我们达到和探索单一生物分子功能中的罕见事件。单分子分析是一种强大的方法，它允许前所未有的生物医学信息的新细节，这是不可能使用传统的平均技术。它有助于我们理解复杂的生物过程（例如癌症等疾病），有必要在单分子水平上识别从单个细胞中提取的蛋白质、DNA、RNA的功能特征。一个可编程的、高效的、一次性的、微型的“智能”系统可以极大地改善我们感兴趣的点上的生物分析。高效的样品处理、隔离、吞吐量、可配置性和大规模分析能力是这种智能小型化实验室芯片系统的关键。该研究项目将首次创新“智能”微/纳米流体技术，通过协同结合3D制造样品机械手和基于可编程液滴的微流体。基于三维特征的样品机械臂可以增强单个生物分子的捕获、分离和转运能力。此外，可编程微流体允许通过实时传感和控制集成芯片上的决策能力。从工程和基础科学的角度来看，该研究将解决一些基本问题，包括：玻璃上的3D微/纳米制造，通过微/纳米尺寸的3D几何形状传输生物分子，不同纳米限制下分子的机械行为，以及使用纳米电润湿的生物分子传输和控制。***我的第一个目标是创建一种具有高纵横比和高精度制造微/纳米特征的3D制造方法，用于生物分子操纵。3D特征，如修改通道，连续约束，后阵列，漏斗和钻石被用于DNA解缠，线性化和易位。传统的制造方法是基于干湿化学蚀刻，具有较高的粗糙度，有限的纵横比和特征质量。在本研究中，将采用一种基于玻璃热变形的新方法进行三维制造。第二个目标是集成可编程流体与三维微/纳米特征。基于可编程液滴的流动将首次与连续约束纳米流体相结合，以实现高通量、更快和大规模的单分子分析。该计划的广泛含义提供了许多有吸引力的应用，包括卫生保健，疾病诊断，药物发现，环境安全，农业和基础研究