Universally applicable three-dimensional hydrodynamic microfluidic flow focusing

Chiu, Yu-Jui; Cho, Sung Hwan; Mei, Zhe; Lien, V.; Wu, Tsung-Feng; Lo, Yu‐Hwa

doi:10.1039/c3lc41202d

Cited by 85 publications

(72 citation statements)

References 35 publications

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“…The potential misalignment in the vertical direction may introduce an artificial broadening of the histogram distribution and thus reduce the sensitivity of the measurement. To address this issue, recently developed hydrodynamic focusing techniques, such as inertial microfluidics 44–49 , 3D symmetric focusing 50–51 and surface acoustic wave microfluidics 52 , could be used.…”

Section: Discussionmentioning

confidence: 99%

Brillouin flow cytometry for label-free mechanical phenotyping of the nucleus

et al. 2017

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The mechanical properties of the nucleus are closely related to many cellular functions; thus, measuring nuclear mechanical properties is crucial to our understanding of cell biomechanics and could lead to intrinsic biophysical contrast mechanisms to classify cells. Although many technologies have been developed to characterize cell stiffness, they generally require contact with the cell and thus cannot provide direct information on nuclear mechanical properties. In this work, we developed a flow cytometry technique based on an all-optical measurement to measure nuclear mechanical properties by integrating Brillouin spectroscopy with microfluidics. Brillouin spectroscopy probes the mechanical properties of material via light scattering, so it is inherently label-free, non-contact, and non-invasive. Using a measuring beam spot of submicron size, we can measure several regions within each cell as they flow, which enables us to classify cell populations based on their nuclear mechanical signatures at a throughput of ~200 cells per hour. We show that Brillouin cytometry has sufficient sensitivity to detect physiologically-relevant changes in nuclear stiffness by probing the effect of drug-induced chromatin decondensation.

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Section: Discussionmentioning

confidence: 99%

Brillouin flow cytometry for label-free mechanical phenotyping of the nucleus

et al. 2017

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“…In the basic HF process, a central solution with a lower flow rate flows within an outer sheath fluid with a higher flow rate, enabling the compression of the central flow [29,30]. This compression decreases mixing times significantly by reducing the required diffusion length [31,32].…”

Section: Hydrodynamic Focusing (Hf) Devicesmentioning

confidence: 99%

“…Later, efforts were made to reduce the number of layers in order to decrease the required fabrication steps and cost. For example, by introducing a height variation in microfluidic channels using two-layer fabrication, focusing on the horizontal and vertical planes can be introduced sequentially to achieve 3D HF (Figure 4a and 4b) [30,57,58]. …”

Section: Hydrodynamic Focusing (Hf) Devicesmentioning

confidence: 99%

Microfluidic hydrodynamic focusing for synthesis of nanomaterials

et al. 2016

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Microfluidics expands the synthetic space such as heat transfer, mass transport, and reagent consumption to conditions not easily achievable in conventional batch processes. Hydrodynamic focusing in particular enables the generation and study of complex engineered nanostructures and new materials systems. In this review, we present an overview of recent progress in the synthesis of nanostructures and microfibers using microfluidic hydrodynamic focusing techniques. Emphasis is placed on distinct designs of flow focusing methods and their associated mechanisms, as well as their applications in material synthesis, determination of reaction kinetics, and study of synthetic mechanisms.

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“…Also the 3D focusing can be achieved through centrifugal forces 6,7 exploiting simple and planar structures, but a crucial point in these cases is represented by the flow rates at which the devices are supposed to work, thus leading to less flexible devices. Finally, few examples of multi-level devices 8,9,10,11,12 proved to be quite efficient in the realization of 3D hydrodynamic focusing also tested as cytometers. Anyway these approaches generally leads to complicated fabrication processes and the devices require the assembly of external component for particle detection and counting.…”

Section: Introductionmentioning

confidence: 98%

“…Furthermore many of the device presented above use three or even more inlets to implement the 3D focusing, while few inlets, enhancing the simplicity of the operations, are to be preferred. In addition, they usually provide asymmetric focusing in the two directions, with the focused sample showing an elliptical cross-section 8 and in several cases flowing close to one edge of the microchannel and not in its center 13 . A different fabrication technique with important advantages with respect to the standard lithographic approaches is femtosecond laser micromachining (FLM) 14 followed by chemical etching.…”

Section: Introductionmentioning

confidence: 99%

Monolithic cell counter based on 3D hydrodynamic focusing in microfluidic channels

2014

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Hydrodynamic focusing is a powerful technique frequently used in microfluidics that presents a wide range of applications since it allows focusing the sample flowing in the device to a narrow region in the center of the microchannel. In fact thanks to the laminarity of the fluxes in microchannels it is possible to confine the sample solution with a low flow rate by using a sheath flow with a higher flow rate. This in turn allows the flowing of one sample element at a time in the detection region, thus enabling analysis on single particles. Femtosecond laser micromachining is ideally suited to fabricate device integrating full hydrodynamic focusing functionalities thanks to the intrinsic 3D nature of this technique, especially if compared to expensive and complicated lithographic multi-step fabrication processes. Furthermore, because of the possibility to fabricate optical waveguides with the same technology, it is possible to obtain compact optofluidic devices to perform optical analysis of the sample even at the single cell level, as is the case for optical cell stretchers and sorters. In this work we show the fabrication and the fluidic characterization of extremely compact devices having only two inlets for 2D (both in vertical and horizontal planes) as well as full 3D symmetric hydrodynamic focusing. In addition we prove one of the possible application of the hydrodynamic focusing module, by fabricating and validating (both with polystyrene beads and erythrocytes) a monolithic cell counter obtained by integrating optical waveguides in the 3D hydrodynamic focusing device.

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Universally applicable three-dimensional hydrodynamic microfluidic flow focusing

Cited by 85 publications

References 35 publications

Brillouin flow cytometry for label-free mechanical phenotyping of the nucleus

Brillouin flow cytometry for label-free mechanical phenotyping of the nucleus

Microfluidic hydrodynamic focusing for synthesis of nanomaterials

Monolithic cell counter based on 3D hydrodynamic focusing in microfluidic channels

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