Uniform mixing in paper-based microfluidic systems using surface acoustic waves

Rezk, Amgad R.; Qi, Aisha; Friend, James; Li, Wai Ho; Yeo, Leslie

doi:10.1039/c2lc21065g

Cited by 150 publications

(111 citation statements)

References 41 publications

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“…24 In the present work, mixing was monitored by "color" measurements. 25 The technique uses the hue instead of the intensity (or brightness), enabling the use of multiple colors in a manner not possible with traditional methods that use grayscale or a specific color channel, for example, the red component of the RGB color space. 24 Concerning pH monitoring, conventional glass-type electrodes have been widely used.…”

Section: Introductionmentioning

confidence: 99%

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Precipitation of hydroxyapatite at 37 °C in a meso oscillatory flow reactor operated in batch at constant power density

et al. 2013

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A meso oscillatory flow reactor (meso-OFR) was successfully applied for the precipitation of hydroxyapatite (HAp) nanoparticles. Mixing efficiency of the mesoreactor operated batchwise in a vertical tube was evaluated at constant power density, by monitoring variation of hue values upon mixing both spatially and temporally. The best operating conditions for fast mixing and a more homogeneous reaction medium were verified for f 5 0.83 Hz and x 0 5 4.5 mm. HAp precipitation was then carried out under these conditions at 37 C for different mixing Ca/P molar ratios. HAp nanoparticles with a mean size (d 50 ) of about 67 nm and a narrow size distribution were obtained. Furthermore, the obtained results show the advantages of the meso-OFR over a stirred tank batch reactor due to the production, about four times faster, of smaller and more uniform HAp nanoparticles.

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Section: Introductionmentioning

confidence: 99%

“…This method has been developed by Rezk et al 25 to evaluate the mixing performance of paper-based microfluidic systems. They proposed hue instead of intensity (or brightness) as an independent means to quantify mixing.…”

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confidence: 99%

Precipitation of hydroxyapatite at 37 °C in a meso oscillatory flow reactor operated in batch at constant power density

et al. 2013

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“…To date, many acoustic-based particle manipulation functions (e.g., focusing, separating, sorting, mixing, and patterning) have been realized (25)(26)(27)(28)(29)(30)(31)(32)(33)(34)(35)(36)(37)(38)(39)(40)(41)(42)(43). None of these approaches, however, have achieved the dexterity of optical tweezers; in other words, none of the previous acoustic-based methods are capable of precisely manipulating single microparticles or cells along an arbitrary path in two dimensions.…”

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confidence: 99%

On-chip manipulation of single microparticles, cells, and organisms using surface acoustic waves

Ding

Lin

Kiraly

et al. 2012

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

790

590

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Techniques that can dexterously manipulate single particles, cells, and organisms are invaluable for many applications in biology, chemistry, engineering, and physics. Here, we demonstrate standing surface acoustic wave based “acoustic tweezers” that can trap and manipulate single microparticles, cells, and entire organisms (i.e., Caenorhabditis elegans ) in a single-layer microfluidic chip. Our acoustic tweezers utilize the wide resonance band of chirped interdigital transducers to achieve real-time control of a standing surface acoustic wave field, which enables flexible manipulation of most known microparticles. The power density required by our acoustic device is significantly lower than its optical counterparts (10,000,000 times less than optical tweezers and 100 times less than optoelectronic tweezers), which renders the technique more biocompatible and amenable to miniaturization. Cell-viability tests were conducted to verify the tweezers’ compatibility with biological objects. With its advantages in biocompatibility, miniaturization, and versatility, the acoustic tweezers presented here will become a powerful tool for many disciplines of science and engineering.

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“…25 We hypothesize that these irregularities would be small for our device because the length-scale of the fibers (pore size: 11 lm) was small in comparison to the microfluidic structures (channel diameter: w p ¼ 1 mm). Furthermore, the orientation of the fibers in Whatman Grade 1 paper is isotropic in the plane of the paper, eliminating irregularities that arise from the orientation of the channels relative to the paper fibers.…”

Section: A Flow Rate Controlmentioning

confidence: 99%

Laser micromachined hybrid open/paper microfluidic chips

2013

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Paper-based microfluidics are an increasingly popular alternative to devices with conventional open channel geometries. The low cost of fabrication and the absence of external instrumentation needed to drive paper microchannels make them especially well suited for medical diagnostics in resource-limited settings. Despite the advantages of paper microfluidics, many assays performed using conventional open channel microfluidics are challenging to translate onto paper, such as bead, emulsion, and cell-based assays. To overcome this challenge, we have developed a hybrid open-channel/paper channel microfluidic device. In this design, wick-driven paper channels control the flow rates within conventional microfluidics. We fabricate these hybrid chips using laser-micromachined polymer sheets and filter paper. In contrast to previous efforts that utilized external, macroscopic paperbased pumps, we integrated micro-scale paper and open channels onto a single chip to control multiple open channels and control complex laminar flow-pattern within individual channels. We demonstrated that flow patterns within the open channels can be quantitatively controlled by modulating the geometry of the paper channels, and that these flow rates agree with Darcy's law. The utility of these hybrid chips, for applications such as bead-, cell-, or emulsion-based assays, was demonstrated by constructing a hybrid chip that hydrodynamically focused micrometer-sized polystyrene beads stably for >10 min, as well as cells, without external instrumentation to drive fluid flow. V C 2013 AIP Publishing LLC.

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Uniform mixing in paper-based microfluidic systems using surface acoustic waves

Cited by 150 publications

References 41 publications

Precipitation of hydroxyapatite at 37 °C in a meso oscillatory flow reactor operated in batch at constant power density

Precipitation of hydroxyapatite at 37 °C in a meso oscillatory flow reactor operated in batch at constant power density

On-chip manipulation of single microparticles, cells, and organisms using surface acoustic waves

Laser micromachined hybrid open/paper microfluidic chips

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