具有宽可调周期的微流控振荡器。
Microfluidic oscillators with widely tunable periods.
机构信息
Department of Biomedical Engineering, University of Michigan, Ann Arbor, MI 48109, USA.
出版信息
Lab Chip. 2013 Apr 21;13(8):1644-8. doi: 10.1039/c3lc41415a.
Abstract
We present experiments and theory of a constant flow-driven microfluidic oscillator with widely tunable oscillation periods. This oscillator converts two constant input-flows from a syringe pump into an alternating, periodic output-flow with oscillation periods that can be adjusted to between 0.3 s to 4.1 h by tuning an external membrane capacitor. This capacitor allows multiple adjustable periods at a given input flow-rate, thus providing great flexibility in device operation. Also, we show that a sufficiently large external capacitance, relative to the internal capacitance of the microfluidic valve itself, is a critical requirement for oscillation. These widely tunable microfluidic oscillators are envisioned to be broadly useful for the study of biological rhythms, as on-chip timing sources for microfluidic logic circuits, and other applications that require variation in timed flow switching.
摘要
我们提出了一种具有广泛可调振荡周期的恒流驱动微流控振荡器的实验和理论。该振荡器将来自注射器泵的两个恒定输入流转换为交替的周期性输出流,通过调节外部膜电容器,振荡周期可以在 0.3 s 到 4.1 h 之间进行调整。该电容器允许在给定输入流速下具有多个可调周期,从而为设备操作提供了极大的灵活性。此外,我们还表明,相对于微流控阀本身的内部电容,足够大的外部电容是振荡的关键要求。这种广泛可调的微流控振荡器有望在生物节律研究、微流控逻辑电路的片上定时源以及其他需要定时流量切换变化的应用中得到广泛应用。
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