Continuous flow separations in microfluidic devices

Pamme, Nicole

doi:10.1039/b712784g

Cited by 713 publications

(616 citation statements)

References 96 publications

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“…For other nonfluorescence-activated cell sorting mechanisms, such as magnetophoresis 77 and acoustophoresis, 78 readers can refer to a number of recently published articles. 12,[79][80][81] …”

Section: Microfluidic Fluorescence-activated Cell Sorter " Facs…mentioning

confidence: 99%

Review Article: Recent advancements in optofluidic flow cytometer

Cho¹,

Godin²,

Chen³

et al. 2010

Biomicrofluidics

141

105

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There is an increasing need to develop optofluidic flow cytometers. Optofluidics, where optics and microfluidics work together to create novel functionalities on a small chip, holds great promise for lab-on-a-chip flow cytometry. The development of a low-cost, compact, handheld flow cytometer and microfluorescence-activated cell sorter system could have a significant impact on the field of point-of-care diagnostics, improving health care in, for example, underserved areas of Africa and Asia, that struggle with epidemics such as HIV/AIDS. In this paper, we review recent advancements in microfluidics, on-chip optics, novel detection architectures, and integrated sorting mechanisms.

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Section: Microfluidic Fluorescence-activated Cell Sorter " Facs…mentioning

confidence: 99%

Review Article: Recent advancements in optofluidic flow cytometer

Cho¹,

Godin²,

Chen³

et al. 2010

Biomicrofluidics

141

105

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“…The separation in the two types of devices were compared and an amplification in the separation of up to 70% was achieved. Numerical [3][4][5][6][7][8][9][10][11][12][13][14] Pinched flow fractionation ͑PFF͒ is a microchip based size separation technique for nanometer to micrometer sized particles relying on a laminar flow sheet. The method was first demonstrated by Yamada et al, 15 where 15 and 30 m polystyrene microspheres were separated.…”

Section: Separation Enhancement In Pinched Flow Fractionationmentioning

confidence: 99%

Separation enhancement in pinched flow fractionation

Vig¹

2008

Applied Physics Letters

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A method for enhancing the separation in the microfluidic size separation technique called pinched flow fractionation (PFF) is demonstrated experimentally and analyzed by numerical calculations. The enhancement is caused by a geometrical modification of the original PFF design. Seven different polystyrene bead sizes ranging from 0.25to2.5μm in radius were separated in a PFF and in an enhanced PFF device. The separation in the two types of devices were compared and an amplification in the separation of up to 70% was achieved. Numerical calculations, which include an edge effect, are used to analyze the device.

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“…The magnetic force needed for separation is provided by magnetic elements integrated in the microdevice itself [3][4][5][6][7][8]; both active and passive elements have been employed. Active elements are primarily electromagnets that consume energy in addition to requiring complex microfabrication processes for their creation [13][14][15].…”

Section: Introductionmentioning

confidence: 99%

Microdevice for continuous flow magnetic separation for bioengineering applications

Khashan

Dagher

Alazzam

et al. 2017

J. Micromech. Microeng.

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A novel continuous flow microfluidic device, integrated with soft-magnetic wire (permalloy), is fabricated and tested for magnetophoresis based separation. The flow-invasive permalloy wire, magnetized using an external bias field, is positioned perpendicular to the external magnetic field and with its length traversing the introduced sample flow. The microfluidic device is realized in PDMS; the mold for PDMS microstructures is cut out of Plexiglas® sheets with controllable dimensions. Microfluidic devices with microchannel height ranging between 0.5 mm and 2 mm are fabricated. Experiments are carried out with and without sheath flow; with sheath flow the microparticles are focused at the center of the microchannel. When focusing is not employed, the microdevice can exhibit a complete separation (or filtration) with the introduction of the sample at rates lower than a maximum threshold. However, this complete separation is attributed to the fact that part of the particles, once they approach the repulsive field of the wire, will find their way into the attractive region of the wire while the remaining will be indefinitely trapped at the channel walls. On the other hand, when the focused sample is flowing at the same rate but alongside an appropriate sheath flow, the complete separation can be achieved with all (initially repelled) particles being captured on the attractive region of the wire itself. This microdevice design is well suited for purification, enrichment, and detection of microparticles in lab-on-a-chip devices due to its ability to handle high throughput without compromising capture efficiency while exhibiting excellent reliability and flexibility.

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Continuous flow separations in microfluidic devices

Cited by 713 publications

References 96 publications

Review Article: Recent advancements in optofluidic flow cytometer

Review Article: Recent advancements in optofluidic flow cytometer

Separation enhancement in pinched flow fractionation

Microdevice for continuous flow magnetic separation for bioengineering applications

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