A hydrodynamic focusing microchannel based on micro-weir shear lift force

Yang, Ruey-Jen; Hou, Hui Hsiung; Wang, Yao Nan; Lin, Che-Hsin; Fu, Lung-Ming

doi:10.1063/1.4739073

Cited by 21 publications

(13 citation statements)

References 51 publications

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“…As a passive manipulation scheme, inertial particle focusing offers significant advantages such as continuous high-throughput processing, non-invasive manipulation without special labels, and simple operation without external fields. 1,2 It has therefore been employed as an important pretreatment strategy for wide-ranging applications such as size-based separation, [3][4][5][6] membrane-free filtration or enrichment, [7][8][9] sheathless microflow cytometry, [10][11][12] efficient solution exchange, 13 high-yield cell-in-droplet encapsulation, 14,15 and large population mechanical phenotyping. 16 With the prosperous development in novel biomedical applications of inertial focusing, the elucidation of the underlying mechanisms has attracted significant attention.…”

Section: Introductionmentioning

confidence: 99%

High-throughput inertial particle focusing in a curved microchannel: Insights into the flow-rate regulation mechanism and process model

et al. 2013

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In this work, we design and fabricate a miniaturized spiral-shaped microchannel device which can be used for high-throughput particle/cell ordering, enrichment, and purification. To probe into the flow rate regulation mechanism, an experimental investigation is carried out on the focusing behaviors of particles with significantly different sizes in this device. A complete picture of the focusing position shifting process is unfolded to clarify the confusing results obtained from flow regimes with different dominant forces in past research. Specifically, with the increase of the flow rate, particles are observed to first move towards the inner wall under the dominant inertial migration, then stabilize at a specific position and finally shift away from the inner wall due to the alternation of the dominant force. Novel phenomena of focusing instability, co-focusing, and focusing position interchange of differently sized particles are also observed and investigated. Based on the obtained experimental data, we develop and validate, for the first time, a five-stage model of the particle focusing process with increasing flow rate for interpreting particle behaviors in terms of the competition between inertial lift and Dean drag forces. These new experimental findings and the proposed process model provide an important supplement to the existing mechanism of inertial particle flow and enable more flexible and precise particle manipulation. Additionally, we examine the focusing behaviors of bioparticles with a polydisperse size distribution to validate the explored mechanisms and thus help realize efficient enrichment and purification of these particles.

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Section: Introductionmentioning

confidence: 99%

High-throughput inertial particle focusing in a curved microchannel: Insights into the flow-rate regulation mechanism and process model

et al. 2013

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“…[3][4][5] Many of the microfluidic diagnosis devices involve particle or cell separation or focusing. [6][7][8][9][10][11] A number of techniques have been investigated for such a purpose, e.g., hydrodynamic filtration, [12][13][14] deterministic lateral displacement (DLD), [15][16][17][18][19] hydrophoresis, 20 and inertial microfluidics. 21,22 The performance of these methods is dictated by a lateral length scale of the microchannel, named as critical diameter, in relation of the particle size.…”

Section: Introductionmentioning

confidence: 99%

Making a hydrophoretic focuser tunable using a diaphragm

et al. 2014

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Microfluidic diagnostic devices often require handling particles or cells with different sizes. In this investigation, a tunable hydrophoretic device was developed which consists of a polydimethylsiloxane (PDMS) slab with hydrophoretic channel, a PDMS diaphragm with pressure channel, and a glass slide. The height of the hydrophoretic channel can be tuned simply and reliably by deforming the elastomeric diaphragm with pressure applied on the pressure channel. This operation allows the device to have a large operating range where different particles and complex biological samples can be processed. The focusing performance of this device was tested using blood cells that varied in shape and size. The hydrophoretic channel had a large cross section which enabled a throughput capability for cell focusing of ∼15 000 cells s−1, which was more than the conventional hydrophoretic focusing and dielectrophoresis (DEP)-active hydrophoretic methods. This tunable hydrophoretic focuser can potentially be integrated into advanced lab-on-a-chip bioanalysis devices.

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“…1 The focusing devices can be categorized as either the active type that uses externally induced forces, [2][3][4][5][6][7][8][9][10][11][12][13] or the passive type that typically uses the hydrodynamic fluid effects. [14][15][16][17][18][19][20][21][22][23][24] Because of the advantages on the simple structure, potential for integration, label free, and biology compatibility, many passive focusing effects have been used in microfluidic devices, such as the sheath flow effect, the hydrodymatic effect, 25,26 the inertial and dean effect, [20][21][22][23][24]27 the hydrophoretic effect, 15,16 etc. The sheath flow method requires more than one input flow at the inlet port and a relatively accurate flow control in order to push the flow with particles existing in the specified position of microfluidic channel.…”

Section: Introductionmentioning

confidence: 99%

Hydrodynamic particle focusing design using fluid-particle interaction

Zhou

Liu

et al. 2013

Biomicrofluidics

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For passive sheathless particles focusing in microfluidics, the equilibrium positions of particles are typically controlled by micro channels with a V-shaped obstacle array (VOA). The design of the obstacles is mainly based on the distribution of flow streamlines without considering the existence of particles. We report an experimentally verified particle trajectory simulation using the arbitrary Lagrangian-Eulerian (ALE) fluid-particle interaction method. The particle trajectory which is strongly influenced by the interaction between the particle and channel wall is systematically analyzed. The numerical experiments show that the streamline is a good approximation of particle trajectory only when the particle locates on the center of the channel in depth. As the advantage of fluid-particle interaction method is achieved at a high computational cost and the streamline analysis is complex, a heuristic dimensionless design objective based on the Faxen's law is proposed to optimize the VOA devices. The optimized performance of particle focusing is verified via the experiments and ALE method.

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A hydrodynamic focusing microchannel based on micro-weir shear lift force

Cited by 21 publications

References 51 publications

High-throughput inertial particle focusing in a curved microchannel: Insights into the flow-rate regulation mechanism and process model

High-throughput inertial particle focusing in a curved microchannel: Insights into the flow-rate regulation mechanism and process model

Making a hydrophoretic focuser tunable using a diaphragm

Hydrodynamic particle focusing design using fluid-particle interaction

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