Microfluidic flow cytometry: The role of microfabrication methodologies, performance and functional specification

Shrirao, Anil B.; Fritz, Z.; Novik, Eric M.; Yarmush, Gabriel; Schloss, Rene S.; Zahn, Jeffrey D.; Yarmush, Martin L.

doi:10.1142/s2339547818300019

Cited by 36 publications

(24 citation statements)

References 199 publications

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“…Sheath fluids are often used to confine particles into a well-defined volume, which, however, requires an accurate control of flow rates. This is because sheath-flow focusing acts upon the suspending fluid, not the suspended particles [11]. Therefore, a variety of forces, which may be externally imposed (termed as active focusing) or internally induced (termed as passive focusing), has been demonstrated to directly manipulate particles for sheath-free focusing [12].…”

Section: Introductionmentioning

confidence: 99%

Passive Dielectrophoretic Focusing of Particles and Cells in Ratchet Microchannels

Malekanfard

Beladi-Behbahani

et al. 2020

Micromachines

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Focusing particles into a tight stream is critical for many microfluidic particle-handling devices such as flow cytometers and particle sorters. This work presents a fundamental study of the passive focusing of polystyrene particles in ratchet microchannels via direct current dielectrophoresis (DC DEP). We demonstrate using both experiments and simulation that particles achieve better focusing in a symmetric ratchet microchannel than in an asymmetric one, regardless of the particle movement direction in the latter. The particle focusing ratio, which is defined as the microchannel width over the particle stream width, is found to increase with an increase in particle size or electric field in the symmetric ratchet microchannel. Moreover, it exhibits an almost linear correlation with the number of ratchets, which can be explained by a theoretical formula that is obtained from a scaling analysis. In addition, we have demonstrated a DC dielectrophoretic focusing of yeast cells in the symmetric ratchet microchannel with minimal impact on the cell viability.

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Section: Introductionmentioning

confidence: 99%

Passive Dielectrophoretic Focusing of Particles and Cells in Ratchet Microchannels

Malekanfard

Beladi-Behbahani

et al. 2020

Micromachines

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“…The material chosen for electrode fabrication depends on its electrochemical properties and manufacturability. Gold (Au) is commonly used because it is electrochemically stable and biologically inert, but other materials like Silver (Ag), Platinum (Pt), Nickel (Ni), and even liquid electrodes made by inserting Silver/Silver Chloride (Ag/AgCl) wires in conductive electrolyte solution have also been demonstrated (Shrirao et al, 2018). Although several variations of electrode configurations exist, the two most common configurations adopted in microfluidic devices are the co-planar and parallel electrode arrangements.…”

Section: Automatic Cell Countingmentioning

confidence: 99%

Cell Cytometry: Review and Perspective on Biotechnological Advances

Vembadi

Menachery

Qasaimeh

2019

Front. Bioeng. Biotechnol.

115

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Cell identification and enumeration are essential procedures within clinical and research laboratories. For over 150 years, quantitative investigation of body fluids such as counts of various blood cells has been an important tool for diagnostic analysis. With the current evolution of point-of-care diagnostics and precision medicine, cheap and precise cell counting technologies are in demand. This article reviews the timeline and recent notable advancements in cell counting that have occurred as a result of improvements in sensing including optical and electrical technology, enhancements in image processing capabilities, and contributions of micro and nanotechnologies. Cell enumeration methods have evolved from the use of manual counting using a hemocytometer to automated cell counters capable of providing reliable counts with high precision and throughput. These developments have been enabled by the use of precision engineering, micro and nanotechnology approaches, automation and multivariate data analysis. Commercially available automated cell counters can be broadly classified into three categories based on the principle of detection namely, electrical impedance, optical analysis and image analysis. These technologies have many common scientific uses, such as hematological analysis, urine analysis and bacterial enumeration. In addition to commercially available technologies, future technological trends using lab-on-a-chip devices have been discussed in detail. Lab-on-a-chip platforms utilize the existing three detection technologies with innovative design changes utilizing advanced nano/microfabrication to produce customized devices suited to specific applications.

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“…Flow cytometry is now quite advanced and allows sorting of tens of thousands of cells per second by as many as 14 parameters [79]. The primary advantage of microfluidics in comparison with cytometry is its portability, with applications to point of care diagnostics, as well as reduced sample volumes and more precise and stable flow control [80]. However, microfluidics and cytometry are not in opposition to each other, and, increasingly, these methods are integrated to develop highly efficient cytometers with diversified functionality in cell sorting, counting, lysis and single cell analyses on a single chip [81].…”

Section: Challenges and Opportunitiesmentioning

confidence: 99%

Microfluidic techniques for separation of bacterial cells via taxis

Gurung¹,

Gel²,

Baker³

2020

Microb Cell

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The microbial environment is typically within a fluid and the key processes happen at the microscopic scale where viscosity dominates over inertial forces. Microfluidic tools are thus well suited to study microbial motility because they offer precise control of spatial structures and are ideal for the generation of laminar fluid flows with low Reynolds numbers at microbial lengthscales. These tools have been used in combination with microscopy platforms to visualise and study various microbial taxes. These include establishing concentration and temperature gradients to influence motility via chemotaxis and thermotaxis, or controlling the surrounding microenvironment to influence rheotaxis, magnetotaxis, and phototaxis. Improvements in microfluidic technology have allowed fine separation of cells based on subtle differences in motility traits and have applications in synthetic biology, directed evolution, and applied medical microbiology.

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Microfluidic flow cytometry: The role of microfabrication methodologies, performance and functional specification

Cited by 36 publications

References 199 publications

Passive Dielectrophoretic Focusing of Particles and Cells in Ratchet Microchannels

Passive Dielectrophoretic Focusing of Particles and Cells in Ratchet Microchannels

Cell Cytometry: Review and Perspective on Biotechnological Advances

Microfluidic techniques for separation of bacterial cells via taxis

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