Controlled manipulation of particles from very large volumes of fluid at high throughput is critical for many biomedical, environmental and industrial applications. One promising approach is to use microfluidic technologies that rely on fluid inertia or elasticity to drive lateral migration of particles to stable equilibrium positions in a microchannel. Here, we report on a hydrodynamic approach that enables deterministic focusing of beads, mammalian cells and anisotropic hydrogel particles in a microchannel at extremely high flow rates. We show that on addition of micromolar concentrations of hyaluronic acid, the resulting fluid viscoelasticity can be used to control the focal position of particles at Reynolds numbers up to Re ≈ 10,000 with corresponding flow rates and particle velocities up to 50 ml min−1 and 130 ms−1. This study explores a previously unattained regime of inertio-elastic fluid flow and demonstrates bioparticle focusing at flow rates that are the highest yet achieved.
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机译:对于许多生物医学,环境和工业应用而言,以高通量控制来自大量流体的颗粒的受控处理至关重要。一种有前途的方法是使用依靠流体惯性或弹性的微流体技术来驱动颗粒的横向迁移到微通道中的稳定平衡位置。在这里,我们报告了一种流体动力学方法,该方法可以使微通道中的珠子,哺乳动物细胞和各向异性水凝胶颗粒以极高的流量进行确定性聚焦。我们表明,添加微摩尔浓度的透明质酸后,所得的流体粘弹性可用于控制雷诺数高达Re≈10,000的粒子的焦点位置,相应的流速和粒子速度可达50 ml min - 1 和130 ms -1 。这项研究探索了以前无法实现的惰性弹性流体流动机制,并证明了生物粒子聚焦于迄今为止达到的最高流速。
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