Microfluidics for automating and integrating synthetic biology

用于自动化和集成合成生物学的微流控

• 批准号: RGPIN-2016-06712
• 负责人: Shih, Steve
• 金额: $ 2.26万
• 依托单位: Concordia University
• 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=683970
• 关键词: Microfluidics; automating; integrating; synthetic; biology

Synthetic biology has been used to engineer complex biological systems in areas such as therapeutics, bioenergy, and biological materials. However, this has been limited by two challenges: scalability and integrating automation of the synthetic biology Design-Build-Test-Learn workflow. Current research laboratories are equipped with robots that are aimed to accelerate synthetic biology and provide high-throughput solutions; however, they require more effort to instruct a robot to perform a new task than saving the researcher time in performing the task. Furthermore, they are expensive -- well outside of the budgetary reach of many scientific laboratories and have large footprints making it difficult for systems integration. Therefore, there is a need to create new automation technologies to expedite the synthetic biology workflow with the advantages of reducing costs and time while increasing the complexity of the biological systems that are created.***In response to this challenge, the proposed research program is to develop microfluidic automation platforms for synthetic biology. This new tool will be powered by digital microfluidics (DMF), a fluid handling technique in which ~nL volumes can be manipulated in parallel on a patterned array of electrodes. To facilitate high-throughput applications, we will integrate DMF with droplet-in-channels a two-phase system where it uses immiscible phases to create emulsions of monodisperse droplets that can act as microreactors containing a single cell or a cocktail of chemical reagents. To facilitate automation, these two microfluidic paradigms will be used together to create droplets containing DNA libraries that are transformed into bacteria or yeast and the functionality of these variants will be evaluated on the basis of directed evolution screening. This research program spans two streams: (1) development of a Microfluidic Automation and Characterization Station (M.A.C.S), and (2) microfluidic integration of the synthetic biology cycle. ***The proposed research program will enable new automation technologies with reduced costs, time, and manual intervention; in addition, the automation system will be inexpensive, will have no moving parts and a small laboratory footprint. In parallel, with developing microfluidics for synthetic biology, a M.A.C.S will enable (a) automatic reagent delivery to the microfluidics, (b) automation of droplet movement, (c) in-line detection system for rapid analysis. This system will be characterized by implementing synthetic biology to discover newly engineered microbes for biofuel production. If successful, this method could transform the field of automation and synthetic biology, and making it accessible for basic and applied scientists to solve problems that could transform other areas such as manufacturing, food production, and healthcare in Canada (and world-wide).*****

合成生物学已被用于在治疗、生物能源和生物材料等领域设计复杂的生物系统。然而，这受到两个挑战的限制：合成生物学设计-构建-测试-学习工作流程的可扩展性和集成自动化。目前的研究实验室配备了旨在加速合成生物学并提供高通量解决方案的机器人;然而，它们需要更多的努力来指导机器人执行新任务，而不是节省研究人员执行任务的时间。此外，它们价格昂贵-远远超出了许多科学实验室的预算范围，而且占地面积大，难以进行系统集成。因此，需要创建新的自动化技术来加快合成生物学工作流程，其优点是降低成本和时间，同时增加所创建的生物系统的复杂性。为了应对这一挑战，拟议的研究计划是开发用于合成生物学的微流体自动化平台。这种新工具将由数字微流体（DMF）提供动力，这是一种流体处理技术，可以在图案化的电极阵列上并行操作~nL体积。为了促进高通量应用，我们将DMF与液滴通道（droplet-in-channels）相结合，这是一种两相系统，在该系统中，它使用不混溶相来产生单分散液滴的乳液，该乳液可以用作含有单个细胞或化学试剂混合物的微反应器。为了促进自动化，这两种微流体范例将一起用于创建含有DNA文库的液滴，所述DNA文库被转化成细菌或酵母，并且这些变体的功能性将基于定向进化筛选进行评估。该研究计划包括两个方面：（1）开发微流控自动化和表征站（M.A.C.S），以及（2）合成生物学循环的微流控集成。* 拟议的研究计划将实现新的自动化技术，减少成本，时间和人工干预;此外，自动化系统将是廉价的，没有移动部件和小的实验室占地面积。与此同时，随着合成生物学微流体技术的发展，M.A.C.S将实现（a）自动试剂输送到微流体，（B）液滴移动的自动化，（c）用于快速分析的在线检测系统。该系统的特点是实施合成生物学，以发现用于生物燃料生产的新工程微生物。如果成功，这种方法可以改变自动化和合成生物学领域，并使基础和应用科学家能够解决可能改变加拿大（和世界范围内）制造业，食品生产和医疗保健等其他领域的问题。