Passive Dielectrophoretic Focusing of Particles and Cells in Ratchet Microchannels

Lu, Song-Yu; Malekanfard, Amirreza; Beladi-Behbahani, Shayesteh; Zu, Wuzhou; Kale, Akshay; Tzeng, Tzuen‐Rong; Wang, Yaonan; Xuan, Xiangchun

doi:10.3390/mi11050451

Cited by 17 publications

(20 citation statements)

References 61 publications

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“…Mentioned previously, yeast cells provide a great basis for the testing of novel EK techniques, specifically when the extended use may apply to other types of prokaryotic or eukaryotic cells. Recent DEP studies for lab‐on‐a‐chip technology and integrated system designs have the common theme of using yeast as a model organism with great interest in cell response to thermal shock and viability as well as differentiation in ratchet microchannels [32–34]. Many bioanalytical applications require rapid sorting of cells, which can be achieved by focusing the particles of interest into a stream within a microchannel; this is especially useful for developing integrated systems that seek to perform multiple functions within a single device.…”

Section: Analyzing and Sensing Of Bacteria And Yeast Cellsmentioning

confidence: 99%

“…provides more insight into particle focusing specifically in ratchet microchannels. This group utilizes yeast as a test particle to prove that the viability of particles will remain high despite Joule heating‐induced temperature elevation [32]. They tested three ratcheting strategies: symmetric, asymmetric forward, and asymmetric backward as depicted in Fig.…”

Section: Analyzing and Sensing Of Bacteria And Yeast Cellsmentioning

confidence: 99%

“…The top channel, a symmetric ratchet with a forward (to the right) velocity of cells, proves to be the most effective, while the bottom channel, an asymmetric ratchet with a backward (to the left) velocity of cells proves to be the most ineffective. Adapted from [32], open access article under Creative International Public License 4.0 (2020). (C) Scanning electron microscope images of viable and a non‐viable heat‐exposed yeast cells and Illustration of the two‐electrode system employed for the quick assessment of cell viability by Fernando‐Juan et al.…”

Section: Analyzing and Sensing Of Bacteria And Yeast Cellsmentioning

confidence: 99%

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Analysis of microorganisms with nonlinear electrokinetic microsystems

Hakim

Lapizco‐Encinas

2021

Electrophoresis

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Nonlinear electrokinetics (EK), specifically electrophoresis of the second kind, dielectrophoresis (DEP) and electrorotation (EROT), have gained significant interest recently for their flexibility and labeless discriminant manner of operation. The current applications of these technologies are a clear advancement from what they were when first discovered, but also still show strong signs of future growth. The present review article presents a discussion of the current uses of microscale nonlinear EK technologies as analytical, sensing, and purification tools for microorganisms. The discussion is focused on some of the latest discoveries with various nonlinear EK microfluidic techniques, such as DEP particle trapping and EROT for particle assessments, for the analysis of microorganisms ranging from viruses to parasites. Along the way, special focus was given to key research articles from within the past two years to provide the most up‐to‐date knowledge on the current state‐of‐the‐art within the field of microscale EK, and from there, an outlook on where the future of the field is headed is also included.

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Section: Analyzing and Sensing Of Bacteria And Yeast Cellsmentioning

confidence: 99%

Section: Analyzing and Sensing Of Bacteria And Yeast Cellsmentioning

confidence: 99%

Section: Analyzing and Sensing Of Bacteria And Yeast Cellsmentioning

confidence: 99%

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Analysis of microorganisms with nonlinear electrokinetic microsystems

Hakim

Lapizco‐Encinas

2021

Electrophoresis

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“…Numerous groups have utilized iEK microfluidic techniques for the study and manipulation of DNA [ 23 , 24 , 25 ], proteins [ 26 , 27 , 28 ], viruses [ 9 , 10 , 11 ], bacteria [ 13 , 15 , 19 ], yeast [ 29 , 30 , 31 ], mammalian cells [ 32 , 33 , 34 , 35 ], and even parasites [ 20 ]. All of these studies illustrate the growing interest in the development of iEK microfluidic systems for microorganism analysis.…”

Section: Introductionmentioning

confidence: 99%

Determination of the Empirical Electrokinetic Equilibrium Condition of Microorganisms in Microfluidic Devices

2020

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The increased concern regarding emerging pathogens and antibiotic resistance has drawn interest in the development of rapid and robust microfluidic techniques to analyze microorganisms. The novel parameter known as the electrokinetic equilibrium condition (EEEC) was presented in recent studies, providing an approach to analyze microparticles in microchannels employing unique electrokinetic (EK) signatures. While the EEEC shows great promise, current estimation approaches can be time-consuming or heavily user-dependent for accurate values. The present contribution aims to analyze existing approaches for estimating this parameter and modify the process into an accurate yet simple technique for estimating the EK behavior of microorganisms in insulator-based microfluidic devices. The technique presented here yields the parameter called the empirical electrokinetic equilibrium condition (eEEEC) which works well as a value for initial approximations of trapping conditions in insulator-based EK (iEK) microfluidic systems. A total of six types of microorganisms were analyzed in this study (three bacteria and three bacteriophages). The proposed approach estimated eEEEC values employing images of trapped microorganisms, yielding high reproducibility (SD 5.0–8.8%). Furthermore, stable trapping voltages (sTVs) were estimated from eEEEC values for distinct channel designs to test that this parameter is system-independent and good agreement was obtained when comparing estimated sTVs vs. experimental values (SD 0.3–19.6%). The encouraging results from this work were used to generate an EK library of data, available on our laboratory website. The data in this library can be used to design tailored iEK microfluidic devices for the analysis of microorganisms.

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“…Compared to passive techniques, active techniques commonly involve higher costs as they require additional devices to produce external fields, and some additional work may be needed in active techniques such as the magnetic labeling of non-magnetic particles. 10 On the contrary, passive techniques are simpler and easy to implement. So they have attracted more attention in the past years, such as the inertial focusing of microparticles, 11 the separation of blood cells via the pinched flow, 12 or the crossflow.…”

Section: Introductionmentioning

confidence: 99%

An IB-LBM design of a microfluidics-based cell capture system

Tang

et al. 2020

Proceedings of the Institution of Mechanical Engineers, Part C:

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The capture of cells in a microfluidic device based on U-shaped sieves is numerically investigated by the immersed boundary-lattice Boltzmann method (IB-LBM). The effects of the width of the inlet ( h), the radius of sieves ([Formula: see text]), and the radius of posts ([Formula: see text]) on the efficiency of the device on trapping cells are studied. It is found that a narrower inlet improves the capability of the device to capture cells and promotes the uniform trapping of cells. In addition, the device is not sufficiently efficient in capturing cells when the radius [Formula: see text] is small. By increasing [Formula: see text] gradually, the cells trapped in the device are found to grow up first and then decrease. This can be explained as an optimal size of apertures between posts to induce the cells to enter the sieve, and then the cells can plug up these apertures. Finally, the effects of the post size on the cell-capturing are studied. It is found that more cells can be captured as [Formula: see text] experiences a slight increase, while the capturing efficiency will not improve if continuing to increase [Formula: see text].

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Passive Dielectrophoretic Focusing of Particles and Cells in Ratchet Microchannels

Cited by 17 publications

References 61 publications

Analysis of microorganisms with nonlinear electrokinetic microsystems

Analysis of microorganisms with nonlinear electrokinetic microsystems

Determination of the Empirical Electrokinetic Equilibrium Condition of Microorganisms in Microfluidic Devices

An IB-LBM design of a microfluidics-based cell capture system

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