High-throughput nanoscale liposome formation via electrohydrodynamic-based micromixer

Trabzon, Levent; Khosroshahi, Ghader Karimian; Khosroshahi, Alireza Rostamzadeh; Gül, Bahar İrem; Bakhshayesh, A. Ghaffarzadeh; Koçak, Alper Furkan; Akyıldız, Direnç; Aldi, Yunus Emre

doi:10.1063/5.0117073

Cited by 17 publications

(10 citation statements)

References 68 publications

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“…In general, microfluidic chips are composed of several branch channels used for injecting two or more fluids, and the angles between the channels are also varied. Micromixers, one of the applications of microfluidic chips, have several branch channels, and the lengths and angles between channels are very important for the efficiency of the fluid mixing [ 20 , 21 , 22 ]. When machining branch channels using microtools, the sizes of the cracks vary depending on the tool feed direction.…”

Section: Resultsmentioning

confidence: 99%

Microfluidic Chip Fabrication of Fused Silica Using Microgrinding

Lee

Sim

et al. 2022

Micromachines

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Although glass is in high demand as a material for microfluidic chips, it is still difficult to fabricate microstructures on glass. In this paper, polycrystalline diamond tools were fabricated through electrical discharge machining, and the microgrinding process for fused silica using the tools was studied. In order to improve the productivity, the machining effects of the high feed rate and depth of cut on the surface roughness of the channel bottoms and edge chipping were studied. A toolpath for the microchannels of a microfluidic chip was also studied and a microfluidic chip array was fabricated using this method.

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Section: Resultsmentioning

confidence: 99%

Microfluidic Chip Fabrication of Fused Silica Using Microgrinding

Lee

Sim

et al. 2022

Micromachines

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“…Passive methods rely on physical differences in cell size, shape, or deformability to separate cells, whereas active methods use external forces to manipulate cells. Some of the mainstream active methods are dielectrophoresis (DEP), electrophoresis, acoustic separation, optical tweezers, and magnetophoresis [16][17][18]. The DEP method applies an electric field to cells, allowing for their separation based on their electrical properties [19].…”

Section: Introductionmentioning

confidence: 99%

A Low-Cost Laser-Prototyped Microfluidic Device for Separating Cells and Bacteria

Gucluer,

Guler

2023

Applied Sciences

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Simple and rapid fabrication of microfluidic devices can enable widespread implementation of lab-on-chip devices in resource-limited environments. However, currently most of the microfluidic devices are fabricated in cleanroom facilities that are well-funded and not accessible to most of the researchers in developing countries. Herein, a simple, low-cost, and reliable method is shown to fabricate microfluidic devices for separating cells and bacteria-size microparticles. For this purpose, serpentine and spiral microfluidic channels are designed and fabricated using rapid laser prototyping. This single inlet microfluidic device is shown to successfully separate yeast cells and smaller microparticles with an efficiency of 85% which is very promising for many lab-on-chip applications including cell-based diagnostics and therapeutics.

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“…Microfluidic chips offer precise control over microfluidic flows by utilizing specialized channel structures, such as the Y-shaped junction and serpentine channel, and enhance the efficiency of heat and mass transfer. Thus, microfluidic chips have been extensively used in various applications including organic synthesis [1][2][3] , chemical analysis [4][5][6] and chip cooling [7][8][9] . However, with the continuous advancement of microfluidic chips, the complexity of channel structures has increased and led to complex three-dimensional (3D) microfluidic flows such as the vortex flow [10][11][12] and droplet flow [13][14][15] .…”

Section: Introductionmentioning

confidence: 99%

High-resolution microscale velocity field measurement using light field particle image-tracking velocimetry

Gu,

Li,

Hossain

et al. 2023

Physics of Fluids

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Light field microparticle image velocimetry (LF-μPIV) can realize the three-dimensional (3D) microscale velocity field measurement, but the spatial resolution of the velocity field is low. Therefore, this study proposes a high-resolution LF particle image-tracking velocimetry (PIV–PTV) in combination with a cross-validation matching (CVM) algorithm. The proposed method performs motion compensation for the distribution of particle center position based on the low-resolution velocity field achieved by PIV and then conducts the CVM on tracer particles with the nearest neighbor method. The motion compensation reduces the particle displacement during the matching, while the CVM reduces the impact of missing particles on the matching accuracy. Thus, the proposed method enables precise tracking of individual particles at higher particle concentrations and improves the spatial resolution of the velocity field. Numerical simulations were conducted on the 3D displacement field reconstruction. The influence of interrogation window size, particle diameter, and concentration was analyzed. Experiments were conducted on the microscale 3D velocity field within the microchannel with right-angle bends. Results indicate that the proposed method provides the high-resolution measurement of the microscale 3D velocity field and improves the precision of the velocity field compared to the PTV at higher particle concentrations. It demonstrates that the proposed method outperforms PIV by 26% in resolution and PTV by 76% in precision at a higher particle concentration of 1.5 particles per microlens.

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High-throughput nanoscale liposome formation via electrohydrodynamic-based micromixer

Cited by 17 publications

References 68 publications

Microfluidic Chip Fabrication of Fused Silica Using Microgrinding

Microfluidic Chip Fabrication of Fused Silica Using Microgrinding

A Low-Cost Laser-Prototyped Microfluidic Device for Separating Cells and Bacteria

High-resolution microscale velocity field measurement using light field particle image-tracking velocimetry

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