Micro magnetic stir-bar mixer integrated with parylene microfluidic channels

Ryu, Kee Suk; Shaikh, Kashan; Goluch, Edgar D.; Fan, Zhifang; Liu, Chang

doi:10.1039/b403305a

Cited by 214 publications

(142 citation statements)

References 25 publications

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“…Passive micromixers 1, [8][9][10][11][12] do not require external energy but only depend on the structure of the channel, and the mixing mechanism relies entirely on molecular diffusion or chaotic advection. For achieving a high mixing efficiency, active micromixers usually utilize the disturbance induced by an external field, such as the electric field, [13][14][15][16] the acoustic field, [17][18][19][20] and the magnetic field, 21,22 etc. However, it is often difficult to fabricate active micromixers for their integration with complicated components that trigger external fields.…”

Section: Introductionmentioning

confidence: 99%

An effective splitting-and-recombination micromixer with self-rotated contact surface for wide Reynolds number range applications

2013

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It is difficult to mix two liquids on a microfluidic chip because the small dimensions and velocities effectively prevent the turbulence. This paper describes two 2-layer PDMS passive micromixers based on the concept of splitting and recombining the flow that exploits a self-rotated contact surface to increase the concentration gradients to obtain fast and efficient mixing. The designed micromixers were simulated and the mixing performance was assessed. The mixers have shown excellent mixing efficiency over a wide range of Reynolds number. The mixers were reasonably fabricated by multilayer soft lithography, and the experimental measurements were performed to qualify the mixing performance of the realized mixer. The results show that the mixing efficiency for one realized mixer is from 91.8% to 87.7% when the Reynolds number increases from 0.3 to 60, while the corresponding value for another mixer is from 89.4% to 72.9%. It is rather interesting that the main mechanism for the rapid mixing is from diffusion to chaotic advection when the flow rate increases, but the mixing efficiency has not obvious decline. The smart geometry of the mixers with total length of 10.25 mm makes it possible to be integrated with many microfluidic devices for various applications in l-TAS and Lab-on-a-chip systems. V C 2013 AIP Publishing LLC.

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Section: Introductionmentioning

confidence: 99%

An effective splitting-and-recombination micromixer with self-rotated contact surface for wide Reynolds number range applications

2013

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“…Gong and W. Wen Biomicrofluidics 3, 012007 ͑2009͒ et al 48 developed an acoustically driven mixer based on the acoustic microstreaming principle; Shilton et al 49 demonstrated increased efficiency in particle concentration/separation and in generating intense micromixing in microliter drops by using concentric circular and elliptical transducers to focus the wave͒, and magnetohydrodynamics ͑Ryu et al 50 fabricated a magnetic stir bar composed of a free rotating rotor to which was applied a rotating external magnetic field͒. A cross-stream active mixer represents a system in which the flow in the main microfluidic channel is perturbed by actively controlled side-channel flows.…”

Section: -6mentioning

confidence: 99%

Polydimethylsiloxane-based conducting composites and their applications in microfluidic chip fabrication

Gong

Wen

2009

Biomicrofluidics

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This paper reviews the design and fabrication of polydimethylsiloxane ͑PDMS͒-based conducting composites and their applications in microfluidic chip fabrication. Owing to their good electrical conductivity and rubberlike elastic characteristics, these composites can be used variously in soft-touch electronic packaging, planar and three-dimensional electronic circuits, and in-chip electrodes. Several microfluidic components fabricated with PDMS-based composites have been introduced, including a microfluidic mixer, a microheater, a micropump, a microdroplet controller, as well as an all-in-one microfluidic chip.

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“…In particular, microrobots on a chip have great advantages for the treatment of biological cells with high throughput, due to their high speed and high accuracy [3]. Several actuation methods of microrobots OPEN ACCESS have been proposed for microscale cell manipulation, such as optical tweezers [4,5], magnetic actuators [6,7] and bubble robots driven by optically induced thermocapillary flow [8]. In previous studies, we proposed magnetically driven micro-tools (MMTs) for on-chip cell manipulation [9][10][11][12].…”

Section: Introductionmentioning

confidence: 99%

Fabrication of Nanopillar Micropatterns by Hybrid Mask Lithography for Surface-Directed Liquid Flow

2013

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This paper presents a novel method for fabricating nanopillar micropatterns for surface-directed liquid flows. It employs hybrid mask lithography, which uses a mask consisting of a combination of a photoresist and nanoparticles in the photolithography process. The nanopillar density is controlled by varying the weight ratio of nanoparticles in the composite mask. Hybrid mask lithography was used to fabricate a surface-directed liquid flow. The effect of the surface-directed liquid flow, which was formed by the air-liquid interface due to nanopillar micropatterns, was evaluated, and the results show that the oscillation of microparticles, when the micro-tool was actuated, was dramatically reduced by using a surface-directed liquid flow. Moreover, the target particle was manipulated individually without non-oscillating ambient particles.

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Micro magnetic stir-bar mixer integrated with parylene microfluidic channels

Cited by 214 publications

References 25 publications

An effective splitting-and-recombination micromixer with self-rotated contact surface for wide Reynolds number range applications

An effective splitting-and-recombination micromixer with self-rotated contact surface for wide Reynolds number range applications

Polydimethylsiloxane-based conducting composites and their applications in microfluidic chip fabrication

Fabrication of Nanopillar Micropatterns by Hybrid Mask Lithography for Surface-Directed Liquid Flow

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