Department of Mechanical and Industrial Engineering, University of Illinois at Chicago, Chicago, USA.
Lab Chip. 2019 Sep 10;19(18):3045-3053. doi: 10.1039/c9lc00484j.
The majority of microfluidic devices nowadays are built on rigid or bulky substrates such as glass slides and polydimethylsiloxane (PDMS) slabs, and heavily rely on external equipment such as syringe pumps. Although a variety of micropumps have been developed in the past, few of them are suitable for flexible microfluidics or lab-on-a-foil systems. In this paper, stick-and-play acoustic micropump is built on thin and flexible plastic film by printing microstructures termed defended oscillating membrane equipped structures (DOMES) using two-photon polymerization. Specifically, this new micropump induces rectified flow upon the actuation of acoustic waves, and the flow patterns agree with simulation results very well. More importantly, the developed micropump has the capabilities to generate adjustable flow rates as high as 420 nL min-1, and does not suffer from problems such as bubble instability, gas dissolution, and undesired bubble-trapping that commonly occur in other forms of acoustic micropumps. Since the micropump works in stick-and-play mode, it is reusable after cleaning thanks to the easy separation of covers and substrates. Lastly, the developed micropump is applied for creating a self-pumped single-cell trapping device. The excellent trapping capability of the integrated device proves its potential for long-term studies of biological behaviors of individual cells for biomedical applications.
如今,大多数微流控设备都是基于刚性或笨重的基板(如玻璃载片和聚二甲基硅氧烷(PDMS)板)构建的,并严重依赖于外部设备(如注射器泵)。尽管过去已经开发出了各种微泵,但很少有微泵适合于柔性微流控或箔片上实验室系统。本文通过使用双光子聚合在薄而灵活的塑料薄膜上打印微结构(称为防御式振荡膜配备结构(DOMES))来构建即插即用式声微泵。具体来说,这种新型微泵在声波激励下会产生整流流动,且流动模式与模拟结果非常吻合。更重要的是,所开发的微泵具有产生高达 420nL/min 的可调流速的能力,而且不会出现其他形式的声微泵中常见的不稳定气泡、气体溶解和不期望的气泡捕获等问题。由于微泵以即插即用模式工作,因此在清洁后可以重复使用,这要归功于盖子和基板的易于分离。最后,所开发的微泵被用于创建自泵送单细胞捕获装置。集成装置的出色捕获能力证明了其在生物医学应用中对单个细胞的生物行为进行长期研究的潜力。
