Your search keyword '"Wu Yupan"' showing total 8 results

1. Three-dimensional paper based platform for automatically running multiple assays in a single step

Author

Wu Yupan, Hongyuan Jiang, Yongda Yan, Yukun Ren, and Lianhuan Han

Subjects

Paper, Detection limit, business.industry, Dynamic range, Chemistry, Point-of-care testing, Troponin I, 010401 analytical chemistry, Microfluidics, Single step, Electrochemical Techniques, 02 engineering and technology, Paper based, Folding (DSP implementation), Microfluidic Analytical Techniques, 021001 nanoscience & nanotechnology, 01 natural sciences, Multiplexing, 0104 chemical sciences, Analytical Chemistry, Automation, Colorimetry, 0210 nano-technology, business, Computer hardware

Abstract

Paper based assays are paving the way to automated, simplified, robust and cost-effective point of care testing (POCT). We propose a method for fabricating three dimensional (3D) microfluidic paper based analytical devices (μPADs) via combining thin adhesive films and paper folding, which avoids the use of cellulose powders and the complex folding sequence and simultaneously permits assays in several layers. To demonstrate the effectiveness of this approach, a 3DμPADs was designed to conduct more assays on a small footprint, allowing dual colorimetric and electrochemical detections. More importantly, we further developed a 3D platform for implementing automated and multiplexed ELISA in parallel, since ELISA, a routine and standard laboratory method, has rarely been used in practical analyses outside of the laboratory. In this configuration, complex and multistep diagnostic assays can be carried out with the addition of the sample and buffer in a simple fashion. Using Troponin I as model, the device showed a broad dynamic range of detection with a detection limit of 0.35 ng/mL. Thus, the developed platforms allow for various assays to be cost-effectively carried out on a single 3D device, showing great potential in an academic setting and point of care testing under resource-poor conditions.

Published

2019

2. Label-Free Multitarget Separation of Particles and Cells under Flow Using Acoustic, Electrophoretic, and Hydrodynamic Forces

Author

Daeyeon Lee, Wu Yupan, Rajarshi Chattaraj, Yukun Ren, and Hongyuan Jiang

Subjects

Electrophoresis, Chemistry, 010401 analytical chemistry, Surface acoustic wave, Microfluidics, Sorting, Acoustics, Cell Separation, Dielectrophoresis, Microfluidic Analytical Techniques, 010402 general chemistry, Chip, 01 natural sciences, 0104 chemical sciences, Analytical Chemistry, Sound, Hydrodynamics, Particle, Surface charge, Biological system

Abstract

Multiplex separation of mixed biological samples is essential in a considerable portion of biomedical research and clinical applications. An automated and operator-independent process for the separation of samples is highly sought after. There is a significant unmet need for methods that can perform fractionation of small volumes of multicomponent mixtures. Herein, we design an integrated chip that combines acoustic and electric fields to enable efficient and label-free separation of multiple different cells and particles under flow. To facilitate the connection of multiple sorting mechanisms in tandem, we investigate the electroosmosis (EO)-induced deterministic lateral displacement (DLD) separation in a combined pressure- and DC field-driven flow and exploit the combination of the bipolar electrode (BPE) focusing and surface acoustic wave (SAW) sorting modules. We successfully integrate four sequential microfluidic modules for multitarget separation within a single platform: (i) sorting particles and cells relying on the size and surface charge by adjusting the flow rate and electric field using a DLD array; (ii) alignment of cells or particles within a microfluidic channel by a bipolar electrode; (iii) separation of particles based on compressibility and density by the acoustic force; and (iv) separation of viable and nonviable cells using dielectric properties via the dielectrophoresis (DEP) force. As a proof of principle, we demonstrate the sorting of multiple cell and particle types (polystyrene (PS) particles, oil droplets, and viable and nonviable yeast cells) with high efficiency. This integrated microfluidic platform combines multiple functional components and, with its ability to noninvasively sort multiple targeted cells in a label-free manner relying on different properties, is compatible with high-definition imaging, showing great potential in diverse diagnostic and analysis applications.

Published

2021

3. High-Throughput Separation, Trapping, and Manipulation of Single Cells and Particles by Combined Dielectrophoresis at a Bipolar Electrode Array

Author

Hongyuan Jiang, Likai Hou, Ye Tao, Yukun Ren, and Wu Yupan

Subjects

Electrophoresis, Microfluidics, Nanotechnology, Cell Separation, Saccharomyces cerevisiae, 02 engineering and technology, Trapping, 01 natural sciences, Analytical Chemistry, chemistry.chemical_compound, Lab-On-A-Chip Devices, Electric field, Electrode array, Electrodes, Chemistry, 010401 analytical chemistry, Electric Conductivity, Dielectrophoresis, 021001 nanoscience & nanotechnology, Microspheres, 0104 chemical sciences, Electrode, Polystyrenes, Polystyrene, 0210 nano-technology

Abstract

Microfluidic systems have been developed widely in scaled-down processes of laboratory techniques, but they are usually limited in achieving stand-alone functionalities. It is highly desirable to exploit an integrated microfluidic device with multiple capabilities such as cell separation, single-cell trapping, and cell manipulation. Herein, we reported a microfluidic platform integrated with actuation electrodes, for separating cells and microbeads, and bipolar electrodes, for trapping, rotating, and propelling single cells and microbeads. The separation of cells and microbeads can be first achieved by deflective dielectrophoresis (DEP) barriers. Trapping experiments with yeast cells and polystyrene (PS) microbeads suspended in aqueous solutions with different conductivities were then conducted, showing that both cells and particles can be trapped at the center of wireless electrodes by negative DEP force. Upon application of a rotating electric field, yeast cells exhibit translational movement along the electrode edges, and self-rotation is seen at an array of bipolar electrodes when electrorotational torque and traveling wave DEP force are applied on the cells. The current approach allows us to switch the propulsion and rotation direction of cells by varying the frequency of the applied electric field. Beyond the achievements of single-cell manipulation, this system permits effective control of several particles or cells simultaneously. The integration of parallel sorting and single trapping stages within a microfluidic chip enables the prospect of high-throughput cell separation, single trapping, and large-scale cell locomotion and rotation in a noninvasive and disposable format, showing great potential in single-cell analysis, targeted drug delivery, and surgery.

Published

2018

4. Large-Scale Single Particle and Cell Trapping based on Rotating Electric Field Induced-Charge Electroosmosis

Author

Wu Yupan, Ye Tao, Yukun Ren, Hongyuan Jiang, and Likai Hou

Subjects

Chemistry, business.industry, 010401 analytical chemistry, Analytical chemistry, 02 engineering and technology, Trapping, Electrostatic induction, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Analytical Chemistry, Amplitude, Electric field, Electrode, Electrode array, Optoelectronics, Electric potential, 0210 nano-technology, business, Voltage

Abstract

We propose a simple, inexpensive microfluidic chip for large-scale trapping of single particles and cells based on induced-charge electroosmosis in a rotating electric field (ROT-ICEO). A central floating electrode array, was placed in the center of the gap between four driving electrodes with a quadrature configuration and used to immobilize single particles or cells. Cells were trapped on the electrode array by the interaction between ROT-ICEO flow and buoyancy flow. We experimentally optimized the efficiency of trapping single particles by investigating important parameters like particle or cell density and electric potential. Experimental and numerical results showed good agreement. The operation of the chip was verified by trapping single polystyrene (PS) microspheres with diameters of 5 and 20 μm and single yeast cells. The highest single particle occupancy of 73% was obtained using a floating electrode array with a diameter of 20 μm with an amplitude voltage of 5 V and frequency of 10 kHz for PS microbeads with a 5-μm diameter and density of 800 particles/μL. The ROT-ICEO flow could hold cells against fluid flows with a rate of less than 0.45 μL/min. This novel, simple, robust method to trap single cells has enormous potential in genetic and metabolic engineering.

Published

2016

5. Enhanced model-based design of a high-throughput three dimensional micromixer driven by alternating-current electrothermal flow

Author

Wu Yupan, Yukun Ren, and Hongyuan Jiang

Subjects

Microchannel, Materials science, Natural convection, business.industry, 010401 analytical chemistry, Clinical Biochemistry, Microfluidics, Mixing (process engineering), Micromixer, 02 engineering and technology, Velocimetry, 021001 nanoscience & nanotechnology, 01 natural sciences, Biochemistry, 0104 chemical sciences, Analytical Chemistry, Volumetric flow rate, Optoelectronics, Fluidics, 0210 nano-technology, business

Abstract

We propose a 3D microfluidic mixer based on the alternating current electrothermal (ACET) flow. The ACET vortex is produced by 3D electrodes embedded in the sidewall of the microchannel and is used to stir the fluidic sample throughout the entire channel depth. An optimized geometrical structure of the proposed 3D micromixer device is obtained based on the enhanced theoretical model of ACET flow and natural convection. We quantitatively analyze the flow field driven by the ACET, and a pattern of electrothermal microvortex is visualized by the micro-particle imaging velocimetry. Then, the mixing experiment is conducted using dye solutions with varying solution conductivities. Mixing efficiency can exceed 90% for electrolytes with 0.2 S/m (1 S/m) when the flow rate is 0.364 μL/min (0.728 μL/min) and the imposed peak-to-peak voltage is 52.5 V (35 V). A critical analysis of our micromixer in comparison with different mixer designs using a comparative mixing index is also performed. The ACET micromixer embedded with sidewall 3D electrodes can achieve a highly effective mixing performance and can generate high throughput in the continuous-flow condition.

Published

2016

6. Enhanced particle trapping performance of induced charge electroosmosis

Author

Hongyuan Jiang, Qi Lang, Wu Yupan, Ye Tao, Yankai Jia, Yukun Ren, and Weiyu Liu

Subjects

Range (particle radiation), Materials science, business.industry, 010401 analytical chemistry, Clinical Biochemistry, Relaxation (NMR), Microfluidics, Nanotechnology, 02 engineering and technology, Trapping, Electrostatic induction, 021001 nanoscience & nanotechnology, 01 natural sciences, Biochemistry, 0104 chemical sciences, Analytical Chemistry, Ion, Electrode, Optoelectronics, 0210 nano-technology, Polarization (electrochemistry), business

Abstract

By increasing the number of floating electrodes or enlarging the width of single floating electrode, this work provides effective ways to strongly improve the particle trapping performance of induced charge electroosmosis (ICEO). Particle trapping with double or triple separate narrow floating electrodes increases the effective actuating range of ICEO flow and therefore enhance the optimum trapping ability to be 1.63 or 2.34 times of that with single narrow electrode (width of L=200μm), and the ideal trapping frequency is independent of the electrode number due to the mutual independence of electrochemical ion relaxation over each electrode. Furthermore, using a single wide floating electrode with the effective width equal to three separate narrow floating electrodes (L=600μm) instead of a single narrow one slightly lowers the ideal trapping frequency due to an increase in the characteristic polarization length, but the trapping performance is only up to 1.59 times of that with original single narrow electrode, implying that vertical channel confinement effect may severely suppresses the effective actuating range of ICEO flow and renders the trapping performance not as expected. Trapping experiments over wide floating electrode with different channel height were carried out, showing that the trapping performance increases by correctly increasing the channel height.

Published

2016

7. Fluid pumping and cells separation by DC-biased traveling wave electroosmosis and dielectrophoresis

Author

Yukun Ren, Wu Yupan, Hongyuan Jiang, and Ye Tao

Subjects

Materials science, business.industry, 010401 analytical chemistry, Analytical chemistry, 02 engineering and technology, Dielectrophoresis, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Signal, 0104 chemical sciences, Electronic, Optical and Magnetic Materials, Volumetric flow rate, Wavelength, Electrokinetic phenomena, Materials Chemistry, Electrode array, Optoelectronics, 0210 nano-technology, business, DC bias, Voltage

Abstract

Fluid pumping in microchips using electrokinetic methods has been a hot area of research. This paper mainly investigates effects of DC offset imposed on traveling wave (TW) signal on electroosmotic flow above a spiral electrode array with 800 µm wavelength. The traveling wave voltage with different DC offsets was applied, and four cases were analyzed by superimposing consecutive images. Experiment results indicate that symmetric electrode array energized with DC-biased TW signal can not only generate a prominent improvement in flow rates, but also be capable of altering the flow direction by changing the polarity of electrical signal. Furthermore, such a device can also be used as an effective means to manipulate and separate PS microbeads and cells on their own for very small and non-flowing sample volumes in terms of the combination of the conventional dielectrophoresis (cDEP) forces and traveling wave DEP (twDEP) forces by properly choosing the parameters associated with the Clausius–Mossotti factor (K(w)). Through adjusting the applied frequencies, we successfully separated yeast cells from a mix containing PS microspheres based on the combination of cDEP and twDEP, providing new opportunities for integration with a charge-coupled device for various biomedical diagnostic devices.

Published

2017

8. Effects of discrete-electrode arrangement on traveling-wave electroosmotic pumping

Author

Haitao Ding, Hongyuan Jiang, Yucheng Ding, Weiyu Liu, Jinyou Shao, Yukun Ren, Wang Chunhui, and Wu Yupan

Subjects

Microchannel, Materials science, Faradaic current, Mechanical Engineering, 010401 analytical chemistry, 02 engineering and technology, Mechanics, 021001 nanoscience & nanotechnology, 01 natural sciences, Capacitance, 0104 chemical sciences, Electronic, Optical and Magnetic Materials, Flow velocity, Mechanics of Materials, Electric field, Electrode, Electrode array, Electrical and Electronic Engineering, 0210 nano-technology, Voltage

Abstract

Traveling-wave electroosmotic (TWEO) pumping arises from the action of an imposed traveling-wave (TW) electric field on its own induced charge in the diffuse double layer, which is formed on top of an electrode array immersed in electrolyte solutions. Such a traveling field can be merely realized in practice by a discrete electrode array upon which the corresponding voltages of correct phase are imposed. By employing the theory of linear and weakly nonlinear double-layer charging dynamics, a physical model incorporating both the nonlinear surface capacitance of diffuse layer and Faradaic current injection is developed herein in order to quantify the changes in TWEO pumping performance from a single-mode TW to discrete electrode configuration. Benefiting from the linear analysis, we investigate the influence of using discrete electrode array to create the TW signal on the resulting fluid motion, and several approaches are suggested to improve the pumping performance. In the nonlinear regime, our full numerical analysis considering the intervening isolation spacing indicates that a practical four-phase discrete electrode configuration of equal electrode and gap width exhibits stronger nonlinearity than expected from the idealized pump applied with a single-mode TW in terms of voltage-dependence of the ideal pumping frequency and peak flow rate, though it has a much lower pumping performance. For model validation, pumping of electrolytes by TWEO is achieved over a confocal spiral four-phase electrode array covered by an insulating microchannel; measurement of flow velocity indicates the modified nonlinear theory considering moderate Faradaic conductance is indeed a more accurate physical description of TWEO. These results offer useful guidelines for designing high-performance TWEO microfluidic pumps with discrete electrode array.

Published

2016