Microfluidics without microfabrication

Lutz, Barry; Chen, Jian; Schwartz, Daniel T.

doi:10.1073/pnas.0831077100

Cited by 44 publications

(52 citation statements)

References 30 publications

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“…As a vesicle follows a loop, it is deformed by shear forces and can even be ruptured (23) (P.M. and S.H., unpublished work). Note that the bubble streaming reported here is quite different in f low pattern from that induced by an oscillating solid object (25), such as the cylinders used in a recent application of acoustic streaming in chemical microreactors (26). The biological relevance of acoustic streaming on larger (centimeter) scales is well established (27).…”

mentioning

confidence: 61%

A bubble-driven microfluidic transport element for bioengineering

Marmottant

Hilgenfeldt

2004

Proc. Natl. Acad. Sci. U.S.A.

170

158

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Microfluidics typically uses channels to transport small objects by actuation forces such as an applied pressure difference or thermocapillarity. We propose that acoustic streaming is an alternative means of directional transport at small scales. Microbubbles on a substrate establish well controlled fluid motion on very small scales; combinations (''doublets'') of bubbles and microparticles break the symmetry of the motion and constitute flow transport elements. We demonstrate the principle of doublet streaming and describe the ensuing transport. Devices based on doublet flow elements work without microchannels and are thus potentially cheap and highly parallelizable.

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mentioning

confidence: 61%

A bubble-driven microfluidic transport element for bioengineering

Marmottant

Hilgenfeldt

2004

Proc. Natl. Acad. Sci. U.S.A.

170

158

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“…A more refined method, which is not limited to the study of micromixers, is to apply streak-or streamline analysis. This was shown by Lutz et al, 19,20 who neatly demonstrated 3D steady microstreaming around a cylinder. Although streamline analysis can be employed to illustrate flow behavior, it is not suitable in determining local variations in velocity.…”

Section: Introductionmentioning

confidence: 63%

Electrophoretic partitioning of proteins in two-phase microflows

et al. 2007

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“…This phenomenon can be observed even in a microscopic environment and it is known to induce a local flow around objects. Thus, some studies reported the application of the phenomenon for manipulations of microobject on a chip [16], [17]. Our group also proposed the cell manipulation method based on the vibration-induced flow which is induced by high-speed actuation of magnetically driven microrobot on a chip [18].…”

Section: Concept Of On-chip Cell Manipulationmentioning

confidence: 99%

On-chip cell transportation based on vibration-induced local flow in open chip environment

Hayakawa

Sakuma

Arai

2015

2015 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)

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We present a novel cell manipulation method based on vibration-induced flow in open-chip environment. By applying circular vibration to a chip having micropillar patterns on its surface, local whirling flow is induced around the micropillars. Therefore, by patterning micropillar array on a chip and applying the circular vibration to the chip, we can achieve cell transportation along the array in an open chip environment. We theoretically analyzed this phenomenon with a single micropillar, and experimentally evaluated behaviours of manipulated microbeads with two micropillars. We confirm there are different manipulation modes according to the pitch of micropillars. We designed the micropillar array for an oocyte transportation based on these evaluations. We succeeded in the transportation of oocytes with up to 35.6 µm/s and confirmed that the velocity can be changed by changing the frequency and amplitude of the applied vibration.

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Microfluidics without microfabrication

Cited by 44 publications

References 30 publications

A bubble-driven microfluidic transport element for bioengineering

A bubble-driven microfluidic transport element for bioengineering

Electrophoretic partitioning of proteins in two-phase microflows

On-chip cell transportation based on vibration-induced local flow in open chip environment

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