Droplet-based Microfluidics - Enabling Technology Platform for High-throughput Screening of Material Synthesis, Life Science Research and Food Safety Control

基于液滴的微流控——材料合成、生命科学研究和食品安全控制高通量筛选的使能技术平台

• 批准号: 301008-2013
• 负责人: Ren, Carolyn
• 金额: $ 2.7万
• 依托单位: University of Waterloo
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2016
• 资助国家: 加拿大
• 起止时间: 2016-01-01 至 2017-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=594940
• 关键词: Droplet; based; Microfluidics; Enabling; Technology

Droplet-based microfluidics, which utilizes immiscible fluids to generate nanoliter-sized droplets, has tremendous potential to revolutionize the quality and throughput of current analytical methods for material synthesis, life science research, food safety control and drug discovery applications, among many others. Employing droplets as test tubes was envisioned several decades ago, but, without suitable techniques to consistently produce uniform droplets and then control them at the single droplet level, this technology has achieved limited traction. Recent advances in microfluidics allow uniform droplets to be generated in channel networks at a frequency of kHz; however, an inability to control individual droplets remains a significant barrier to industrial application. Therefore, this research program is designed to strategically address these challenges by systematically: i) investigating the fundamental physics of droplet transport in large-scale channel networks with realistic operating and geometric conditions, which will lead to advanced fundamental knowledge in this field, practically useful design tools, and passive droplet manipulation functions such as droplet splitting and merging; and ii) developing novel microwave technology for remote and simultaneous sensing and heating over individual droplets using metamaterial -inspired resonators (normally used for wireless communications), which will significantly increase the capacity of droplet-based microfluidics and thus open up new application areas such as detection of nano-sized trace metals in fuel oils. This research program will ultimately establish an enabling technology platform for a variety of applications, which will potentially yield enormous impacts on the broad field of micro/nanodevices. Training highly qualified personnel is one of the fundamental focuses of this program, which will provide a unique multidisciplinary training environment through collaborations between the applicant and leading researchers in the proposed application areas, namely material synthesis, life science research and food safety control.

基于液滴的微流体技术利用不混溶的流体产生纳升大小的液滴，具有巨大的潜力，可以彻底改变当前材料合成、生命科学研究、食品安全控制和药物发现应用等分析方法的质量和通量。几十年前就设想了将液滴用作试管，但是，由于没有合适的技术来一致地产生均匀的液滴，然后将它们控制在单个液滴水平，这种技术已经实现了有限的牵引力。微流体技术的最新进展允许以kHz的频率在通道网络中产生均匀的液滴;然而，无法控制单个液滴仍然是工业应用的重大障碍。因此，本研究计划旨在通过系统地解决这些挑战：i）研究具有现实操作和几何条件的大规模通道网络中液滴传输的基本物理学，这将导致该领域的先进基础知识，实用的设计工具和被动液滴操纵功能，如液滴分裂和合并;以及ii）开发新型微波技术，用于使用超材料激发的谐振器（通常用于无线通信）对单个液滴进行远程和同时感测和加热，这将显著增加基于液滴的微流体的容量，从而开辟新的应用领域，例如检测燃料油中的纳米尺寸的痕量金属。该研究计划将最终建立一个使能技术平台，用于各种应用，这将可能对微/纳米器件的广泛领域产生巨大影响。培训高素质的人才是该计划的基本重点之一，该计划将通过申请人与拟议应用领域（即材料合成，生命科学研究和食品安全控制）的领先研究人员之间的合作提供独特的多学科培训环境。