DC-Dielectrophoretic Manipulation and Isolation of Microplastic Particle-Treated Microalgae Cells in Asymmetric-Orifice-Based Microfluidic Chip

Gao, Tianbo; Zhao, Kai; Zhang, Jiaqi; Zhang, Kaihuan

doi:10.3390/mi14010229

Cited by 6 publications

(5 citation statements)

References 36 publications

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“…, a large potential gradient), which always attracts the droplets in the direction of the strongest pole of the field. 75 , 76 In this study, the strongest pole is the discharging needle, and the direction of the droplet elongation is always upward (due to the DEP forces), regardless of the direction of the electric field (in the case of using an AC field). As a result, depending on the conditions in the discharge zone ( i.e.…”

Section: Resultsmentioning

confidence: 75%

“…As this process continues, the elongation causes necking and pinch-off in the deformed droplets. , On the other hand, the DEP forces occur due to a significant difference in potential between the two poles ( i.e. , a large potential gradient), which always attracts the droplets in the direction of the strongest pole of the field. , In this study, the strongest pole is the discharging needle, and the direction of the droplet elongation is always upward (due to the DEP forces), regardless of the direction of the electric field (in the case of using an AC field). As a result, depending on the conditions in the discharge zone ( i.e.…”

Section: Resultsmentioning

confidence: 99%

“…73,74 On the other hand, the DEP forces occur due to a significant difference in potential between the two poles (i.e., a large potential gradient), which always attracts the droplets in the direction of the strongest pole of the field. 75,76 In this study, the strongest pole is the discharging needle, and the direction of the droplet elongation is always upward (due to the DEP forces), regardless of the direction of the electric field (in the case of using an AC field). As a result, depending on the conditions in the discharge zone (i.e., oil viscosity, fluid circulation velocity, and number of already diffused water droplets), either of these forces can act to deteriorate the quality of the emulsions with coalescence and enlargement of the water droplets.…”

Section: Effect Of Oil Viscosity (ν) On Water Droplet Size (D) Under ...mentioning

confidence: 99%

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Impact of Processing Parameters on Contactless Emulsification via Corona Discharge

2023

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A contactless emulsification method is presented using corona discharge. The corona discharge forms using a pin-to-plate configuration, creating a non-uniform electric field. This results in a simultaneous electrohydrodynamic (EHD) pumping of silicone oil and an electroconvection of water droplets that accelerate and submerge inside the oil, leading to a continuous water-in-oil (W/O) emulsion formation process. The impact of the oil viscosity and corona generating AC and DC electric fields (i.e., voltage and frequency) on the characteristics of the emulsions is studied. The emulsification power consumption using the AC and DC electric fields is calculated and compared to traditional emulsion formation methods. While using the DC electric field results in the formation of uniform emulsions, the AC electric field is readily available and uses less power for the emulsification. This is facile, contactless, and energy-efficient for the continuous formation of W/O emulsions.

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Section: Resultsmentioning

confidence: 75%

Section: Resultsmentioning

confidence: 99%

Section: Effect Of Oil Viscosity (ν) On Water Droplet Size (D) Under ...mentioning

confidence: 99%

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Impact of Processing Parameters on Contactless Emulsification via Corona Discharge

2023

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“…Microfluidic separation is mainly categorized into active and passive approaches [6]. Active techniques utilize external fields (electrics [7], magnetics [8], acoustics [9], etc.) to facilitate particle/cell separation.…”

Section: Introductionmentioning

confidence: 99%

High-throughput separation of microalgae on a runway-shaped channel with ordered semicircular micro-obstacles

Hu,

Jin,

Chen

et al. 2024

Preprint

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Microalgae serve as a valuable biological resource in many industrial applications. Thus, it is essential to obtain a high-efficiency separation technique for microalgae precisely. In this study, a runway-shaped microchannel with ordered semicircular micro-obstacles was introduced to conduct the separation of microalgae with different sizes. The runway-shaped microchannel combined the spiral characteristics with a series of semicircular micro-obstacles to realize the advantage of a sheathless, high-throughput, and low aspect ratio configuration. These micro-obstacles improved the performance of particle focusing, which can promote the microalgae separation effectively. These simulated results demonstrated that the runway-shaped channel with ordered semicircular micro-obstacles could form the evident distribution of local Dean vortices to separate particles with different size or volume. When the flow rate is considered 4mL/min, the experiment indicated that the microchannel could separate the Chlorella vulgaris and Haematococcus pluvialis in 94.6% and 81.5%, respectively. The microchannel with the high throughput and separation efficiency is competent to carry out the task of microalgal screening and artificial cultivation.

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“…Different structures of electrodes and channels are designed to perform different functions. Tianbo Gao et al [ 19 ] proposed a novel design of a DC dielectrophoresis microfluidic chip with rectangular electrodes placed on one side of the channel horizontally and electrodes with rectangular teeth on the other side, and successfully separated Chlorella vulgaris coated with 100% PS particles at 3 μm and 6 μm. Pouya Sharbati et al [ 20 ] proposed a novel microfluidic device that successfully isolated four types of cells, red blood cells, T-cells, U937-MC cells and Clostridium difficile bacteria, simultaneously by using two sets of electrodes, a cylindrical electrode and a sidewall rectangular electrode.…”

Section: Introductionmentioning

confidence: 99%

Design of a Low-Frequency Dielectrophoresis-Based Arc Microfluidic Chip for Multigroup Cell Sorting

et al. 2023

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Dielectrophoresis technology is applied to microfluidic chips to achieve microscopic control of cells. Currently, microfluidic chips based on dielectrophoresis have certain limitations in terms of cell sorting species, in order to explore a microfluidic chip with excellent performance and high versatility. In this paper, we designed a microfluidic chip that can be used for continuous cell sorting, with the structural design of a curved channel and curved double side electrodes. CM factors were calculated for eight human healthy blood cells and cancerous cells using the software MyDEP, the simulation of various blood cells sorting and the simulation of the joule heat effect of the microfluidic chip were completed using the software COMSOL Multiphysics. The effect of voltage and inlet flow velocity on the simulation results was discussed using the control variables method. We found feasible parameters from simulation results under different voltages and inlet flow velocities, and the feasibility of the design was verified from multiple perspectives by measuring cell movement trajectories, cell recovery rate and separation purity. This paper provides a universal method for cell, particle and even protein sorting.

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DC-Dielectrophoretic Manipulation and Isolation of Microplastic Particle-Treated Microalgae Cells in Asymmetric-Orifice-Based Microfluidic Chip

Cited by 6 publications

References 36 publications

Impact of Processing Parameters on Contactless Emulsification via Corona Discharge

Impact of Processing Parameters on Contactless Emulsification via Corona Discharge

High-throughput separation of microalgae on a runway-shaped channel with ordered semicircular micro-obstacles

Design of a Low-Frequency Dielectrophoresis-Based Arc Microfluidic Chip for Multigroup Cell Sorting

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