Droplet creation using liquid dielectrophoresis

Dielectrophoresis (DEP) is defined as polarizable particles moving into regions of higher electric field intensity. In liquid DEP (LDEP), a dielectric liquid tends to flow toward regions of high electric field intensity under a non-uniform electric field. This work presents a theoretical model of LDEP based on parallel electrodes. The LDEP force is derived using the lump parameter electromechanical method. The relationship between the minimum actuation voltage and the electrode width is investigated experimentally and theoretically. We also propose a method for creating a 20 nl droplet of deionized water using LDEP. The creation of a water droplet containing 15 μm polystyrene beads is placed at the desired location from a continuous flow driven by LDEP using the developed method.     

A microfluidic device for rapid concentration of particles in continuous flow by DC dielectrophoresis

This article presents a microfluidic device (so called concentrator) for rapid and efficient concentration of micro/nanoparticles using direct current dielectrophoresis (DC DEP) in continuous fluid flow. The concentrator is composed of a series of microchannels constructed with PDMS-insulating microstructures to focus efficiently the electric field in the flow direction to provide high field strength and gradient. Multiple trapping regions are formed within the concentrator. The location of particle trapping depends on the strength of the electric field applied. Under the experimental conditions, both streaming movement and DEP trapping of particles simultaneously take place within the concentrator at different regions. The former occurs upstream and is responsible for continuous transport of the particles, whereas the latter occurs downstream and rapidly traps the particles delivered from upstream. The observation agrees with the distribution of the simulated electric field and DEP force. The performance of the device is demonstrated by successfully and effectively concentrating fluorescent nanoparticles. At the sufficiently high electric field, the device demonstrates a trapping efficiency of 100%, which means downstream DEP traps and concentrates all (100%) the incoming particles from upstream. The trapping efficiency of the device is further studied by measuring the fluorescence intensity of concentrated particles in the channel. Typically, the fluorescence intensity becomes saturated in Trap 1 by applying the voltage (400 V) for >2 min, demonstrating that rapid concentration of the nanoparticles (10⁷ particles/ml) is achieved in the device. The microfluidic concentrator described can be implemented in applications where rapid concentration of targets is needed such as concentrating cells for sample preparation and concentrating molecular biomarkers for detection.     

Performances of a broad range of dielectric stacks for liquid dielectrophoresis transduction

Among digital microfluidic techniques, liquid dielectrophoresis (LDEP) is well adapted to displace insulating liquids. One of the current challenges for LDEP concerns the robustness of both the dielectric and hydrophobic coatings (deposited atop the driving electrodes). Indeed, such layers may be exposed to high electric field, during operation. There is a need to optimize this stack of insulating layers to first prevent from their dielectric breakdown, secondly reduce the actuation voltage, and lastly ensure a reproducible and well-controlled droplet-generation process. For the first time, an extensive study is presented in that paper, comparing the performances of more than twenty different dielectric stacks (including SiN, High-K materials, hydrophobic coatings) from micro–nanoelectronics know-how and implemented onto a given LDEP design. This generic design features lateral bumps regularly spaced across coplanar electrodes to generate an array of 30 pL DI water droplets in a single open-plate architecture. The experiments have been carefully analyzed to identify which are the best stacks in terms of efficiency and quality for the LDEP transduction. As a result to that study, we propose a guideline to adjust the dielectric coating properties (thickness, material) depending on the liquids to displace and targeted applications.     

Performance of multilayered fluoropolymer surface coating for DEP surface microfluidic devices

One of the key structural features of a surface microfluidic (SMF) device is the surface coating, since it directly affects both the performance and reliability of the SMF device. This work examines and compares the performance of liquid dielectrophoresis (LDEP) SMF devices, fabricated with conventional spin-coated Teflon^? surface to those coated with a recently developed fluoropolymer composite coating, which have been shown to be superior for low-voltage electrowetting actuation. We have focused on SMF devices that leverage LDEP and utilize high AC voltages to actuate aqueous samples on hydrophobic surfaces and produce droplet arrays of controlled size and structure to facilitate rapid and large-scale combinatorial bio-assays. Our findings demonstrate the superior performance, robustness and reliability of the composite coating over the conventional spin-coated Teflon^? coating, for repeated high-voltage, high-frequency LDEP actuations for homogenous, emulsion and variable volume aqueous sample dispensing.     

Trapping of cells by insulator-based dielectrophoresis using open-top microstructures

The ability to manipulate biological cells is a fundamental need of many biological and medical applications. Insulator-based dielectrophoresis (iDEP) trapping involves the use of insulating structures that squeeze the electric field in a conductive solution to create a nonuniform electric field. In this work, a microchip was designed and fabricated for iDEP trapping with open-top microstructures. Microelectrodes were deposited on the substrate and the voltage required was minimized by reducing the distance between them. Human carcinoma (HeLa) cells were trapped under different frequencies to demonstrate the usability of the present microchip. Negative and positive dielectrophoresis (DEP) of cells were observed at low and high frequencies, respectively. The open-top microstructures are suitable for trapping cells and biological samples that can then easily undergo further treatment, such as culturing or contact detection. Since the cover is absent in open-top microstructures, there is no interference in the intensity of the emitted light during fluorescent detection. Furthermore, the Joule heat, which is generated by the application of high voltage in the open-top microstructure, can be dissipated more effectively.     

Integrated liquid and droplet dielectrophoresis for biochemical assays

Surface microfluidic systems have emerged as an attractive alternative to conventional closed-channel microfluidic devices. In many such systems, electric fields are leveraged for the manipulation and transport of discrete nanoliter droplets on open planar surfaces. The present research work discusses dielectrophoretic liquid and droplet actuations, which provide an attractive methodology for dispensing and manipulating nanoliter and picoliter droplets on planar surfaces. We demonstrate the integration of two independent sample actuation schemes, namely liquid dielectrophoresis (L-DEP) and droplet dielectrophoresis, and furthermore validate its applicability through model biochemical assays (DNA-PicoGreen^® assay and DNA FRET assay). We also describe and present ‘tapering L-DEP’ actuation scheme, whereby we demonstrate how to simultaneously create multiple droplets of different sizes and volumes in the range of nanoliter and picoliters, from a given larger parent sample droplet.     

Droplet microfluidic preparation of au nanoparticles-coated chitosan microbeads for flow-through surface-enhanced Raman scattering detection

An integrated microfluidic device was fabricated to enable on-chip droplet forming, trapping, fusing, shrinking, reaction and producing functional microbeads for a flow-through single bead-based molecule detection. Dielectrophoresis (DEP) force was used to transport target polymer droplets into different predefined microwells, where the droplets were fused through electrocoalescence to form a new one with a desired diameter. In a continuous water loss process with water diffusion to oil phase, the polymer droplet was shrunken and solidified to form a polymer microbead. For a demonstration, Au nanoparticles-coated chitosan microbeads were in situ fabricated through droplet trapping, fusion and shrinking, followed by synthesis of Au nanoparticles on the microbead surface via a photoreduction process. The produced Au nanoparticle/chitosan microbead embedded in the microwell resulted in a highly sensitive, flow-through surface-enhanced Raman scattering (SERS) detection of Rhodamine 6G (R6G). This work successfully demonstrates an integrated droplet based lab-on-a chip and its application to fabricate an extremely high-throughput single bead based detection platform.     

Precisely sized separation of multiple particles based on the dielectrophoresis gradient in the z-direction

We present a new 3D dielectrophoresis-field-flow fraction (DEP-FFF) concept to achieve precise separation of multiple particles by using AC DEP force gradient in the z-direction. The interlaced electrode array was placed at the upstream of the microchannel, which not only focused the particles into a single particle stream to be at the same starting position for further separation, but also increased the spacing between each particle by the retard effect to reduce particle–particle aggregation. An inclined electrode was also designed in back of the focusing component to continuously and precisely separate different sizes of microparticles. Different magnitudes of DEP force are induced at different positions in the z-direction of the DEP gate, which causes different penetration times and positions of particles along the inclined DEP gate. 2, 3, 4, and 6?μm polystyrene beads were precisely sized fractionation to be four particle streams based on their different threshold DEP velocities that were induced by the field gradient in the z-direction when a voltage of 6.5?V_p–p was applied at a flow rate of 0.6?μl/min. Finally, Candida albicans were also sized separated to be three populations for demonstrating the feasibility of this platform in biological applications. The results showed that a high resolution sized fractionation (only 25% size difference) of multiple particles can be achieved in this DEP-based microfluidic device by applying a single AC electrical signal.     

Selective position of individual cells without lysis on a circular window array using dielectrophoresis in a microfluidic device

We trapped individual cells between two circular windows using negative dielectrophoretic (DEP) force and then sequentially trapped them inside circular windows by positive DEP force without electrical lysis in a microfluidic device. Three parameters, (1) the transmembrane potential that determines the lysis of a cell, (2) individual cell size that affects the trapped position accuracy of the cell, and (3) the Clausius–Mossotti (CM) factor that decides the trapped efficiency of the cell, were characterized experimentally and numerically in this sequential cell trapping technique. In this characterization, we confirmed that the swap rate of applied voltage frequency, size similarity between the cell and circular window, and instantaneous change rate of Re(f _CM) as a function of frequency were important factors in determining the selective position of individual cells without lysis. Our results provide useful suggestions for designing the structure of microfluidic DEP devices and optimizing variables required to manipulate individual cell trapping using both negative and positive DEP forces.     

Fabrication of bio/nano interfaces between biological cells and carbon nanotubes using dielectrophoresis

The authors have previously demonstrated the manipulation of bacteria and carbon nanotubes (CNTs) using dielectrophoresis (DEP) and its application for various types of biological and chemical sensors. This paper demonstrates simultaneous DEP handling of bacteria and CNTs, which are mixed and suspended in water. The CNTs were solubilized in water using microplasma-based treatment. When a microelectrode was energized with an ac voltage in the suspension of Escherichia coli (E. coli) cells and multi-walled CNTs (MWCNTs), both of them were simultaneously trapped in the microelectrode gap. Scanning electron microscopy (SEM) images revealed that E. coli cells were trapped on the surface or the tip of MWCNTs, where the electric field strength was intensified due to high aspect ratio of MWCNTs. As a result, bio/nano interfaces between bacteria and MWCNTs were automatically formed in a self-assembly manner. A potential application of the DEP-fabricated bio/nano interfaces is a drug delivery system (DDS), which is realized by transporting drug molecules from CNTs to cells across the cell membrane, which can be electroporated by the local high electric field formed on the CNT surface.     

Particle streaming and separation using dielectrophoresis through discrete periodic microelectrode array

This study presents a particle manipulation and separation technique based on dielectrophoresis principle by employing an array of isosceles triangular microelectrodes on the bottom plate and a continuous electrode on the top plate. These electrodes generate non-uniform electric fields transversely across the microchannel. The particles within the flowing fluid experience a dielectrophoretic force perpendicular to the fluid flow direction due to the non-uniform electric fields. The isosceles triangular microelectrodes were designed to continuously exert a small dielectrophoretic force on the particles. Particles experiencing a larger dielectrophoretic force would move further in the perpendicular direction to the fluid flow as they traveled past each microelectrode. Polystyrene microspheres were used as the model particles, with particles of ∅20 μm employed for studying the basic characteristics of this technique. Particle separation was subsequently demonstrated on ∅10 and ∅15 μm microspheres. Using an applied sinusoidal voltage of 20 V_pp and frequency of 1 MHz, a mean separation distance of 0.765 mm between them was achieved at a flow rate of 3 μl/min (~1 mm/s), an important consideration for high throughput separation capability in a micro-scale technology device. This unique isosceles triangular microelectrodes design allows heterogeneous particle populations to be separated into multiple streams in a single continuous operation.     

中国微米纳米-碳纳米管可控介电泳参数模拟研究

碳纳米管的结构以及微电极的物性参数是微纳器件制备过程中影响介电泳效率与精度的重要因素.微电极形状和电极间距与碳纳米管长度之比(λ)是两个与器件制造成本紧密相关的可控介电泳参数.本文根据有限元方法,研究了这两个参数对于介电泳力的影响规律.通过对3种电极下的碳纳米管介电泳速度进行归一化处理,结果表明碳纳米管在分散液中的介电泳速度受电极形状影响较小.而相比于电极形状,λ对介电泳力的影响更加显著.虽然电极间距越小越有利于碳纳米管的组装,但是考虑微电极加工难度与成本,认为λ在0.5~1.0为碳纳米管组装的优化区间.根据介电泳组装实验需要,给出了溶液阈值浓度修正表达式.本研究对于提高介电泳组装效率和实验精度具有一定的理论指导意义.     

Simulation and analysis of particle trajectory caused by the optical-induced dielectrophoresis force

Optical-induced dielectrophoresis (ODEP) is a novel technology used in the field of micro-/nanoparticles manipulation. The finite element method was applied for ODEP to research the particles motion in this paper. The potential distribution in the optoelectronic chip, which was induced by the incident light spot, was attained through electric current module in the COMSOL 4.3a. The particles motion was studied by coupling the module of electric current and particle tracing for fluid flow. Compared with molecular dynamics, the method proposed in the paper could effectively simplify the tedious programming. The polystyrene sphere (PS) particles with the radius of 2, 5, 10, and 15 μm were, respectively, used as the objects. The kinetic energy of the PS created by the dielectrophoresis (DEP) forces, the Stokes drag forces, the gravity forces, and the Brownian motion forces was calculated during the whole manipulation process. The simulation results indicated that with the decreasing in the particle size, the time on enrichment of the smaller PS would become longer. It was because that for the smaller PS, the effect of DEP forces would play less important role in the system. The conclusions in this paper could be used as a theoretical guidance in the further research.     

Design of new microchannel to reduce applied voltage for microparticles separation using dielectrophoresis method

This paper presents a new structure of microchannel in order to reduce the applied voltage using dielectrophoresis (DEP). DEP is one of the most popular techniques to separate microparticles which needs an electric field in microfluidic devices. In this study, the AC-DEP sidewall electrodes are used. The novelty of this research is to change the outlet microchannel size which effectively reduces applied voltage. In previous work, in order to separate particles with 3.5 and 4 µm diameters, 4.5 V was needed. In new design, we keep all effective parameters constant and change one of the outlet microchannel size from 50 to 60, 70 and 80 µm. Therefore, in order to separate the microparticles, we need only 3, 2 and 1.3 V, respectively.

     

Electrokinetically driven concentration of particles and cells by dielectrophoresis with DC-offset AC electric field

Insulator-based dielectrophoresis (iDEP) has been successfully used for on-chip manipulations of biological samples. Despite its effectiveness, iDEP typically requires high DC voltages to achieve sufficient electric field; this is mainly due to the coupled phenomena among linear electrokinetics: electroosmosis (EO) and electrophoresis (EP) and nonlinear electrokinetics: dielectrophoresis (DEP). This paper presents a microfluidic technique using DC-offset AC electric field for electrokinetic concentration of particles and cells by repulsive iDEP. This technique introduces AC electric field for producing iDEP which is decoupled from electroosmosis (EO) and electrophoresis (EP). The repulsive iDEP is generated in a PDMS tapered contraction channel that induces non-uniform electric field. The benefits of introducing AC electric field component are threefold: (i) it contributes to DEP force acting on particles, (ii) it suppresses EO flow and (iii) it does not cause any EP motion. As a result, the required DC field component that is mainly used to transport particles on the basis of EO and EP can be significantly reduced. Experimental results supported by numerical simulations showed that the total DC-offset AC electric field strength required to concentrate 15-μm particles is significantly reduced up to 85.9% as compared to using sole DC electric field. Parametric experimental studies showed that the higher buffer concentration, larger particle size and higher ratio of AC-to-DC electric field are favorable for particle concentration. In addition, the proposed technique was demonstrated for concentration of yeast cells.     

Hydrodynamic separation of cells utilizing insulator-based dielectrophoresis

Manipulation and discrimination of biological cells is essential to many biomedical applications. Insulator-based dielectrophoresis (iDEP) trapping consists of insulating structures which squeeze the electric field in a conductive solution to create a non-uniform electric field. The pattern of insulating structure was designed to generate regions of high-electric field to trap cells with positive dielectrophoresis (e.g., dead mammalian cells at low frequency) in lower-flow-field regions. However, negative-dielectrophoretic cells (e.g., viable cells at low frequency) were repelled toward low-electric-field regions where the velocity was higher. Cells with different dielectrophoretic responses were therefore separated and collected in the outlet. Simulations were numerically performed to investigate parameters of the design in the present study. Furthermore, experiments were also conducted to demonstrate the feasibility of hydrodynamic separation using iDEP in the proposed design.     

On-chip separation of Lactobacillus bacteria from yeasts using dielectrophoresis

Dielectrophoresis, the induced motion of dielectric particles in non-uniform electric fields, enables the separation of suspended bio-particles based on their dimensions or dielectric properties. This work presents a microfluidic system, which utilises a combination of dielectrophoretic (DEP) and hydrodynamic drag forces to separate Lactobacillus bacteria from a background of yeasts. The performance of the system is demonstrated at two operating frequencies of 10?MHz and 100?kHz. At 10?MHz, we are able to trap the yeasts and bacteria at different locations of the microelectrodes as they experience different magnitudes of DEP force. Alternatively, at 100?kHz we are able to trap the bacteria along the microelectrodes, while repelling the yeasts from the microelectrodes and washing them away by the drag force. These separation mechanisms might be applicable to automated lab-on-a-chip systems for the rapid and label-free separation of target bio-particles.     

Microparticle Concentration and Separation by Traveling-Wave Dielectrophoresis (twDEP) for Digital Microfluidics

This paper describes highly efficient in-droplet particle concentration and separation where particles are concentrated and separated into droplets by traveling-wave dielectrophoresis (DEP) and subsequent electrowetting-on-dielectric droplet splitting. A successful concentration for 5-mum aldehyde sulfate (AS) latex particles was experimentally achieved using microfabricated devices, showing that 98% of the total particles were concentrated into a split daughter droplet. In addition, in-droplet particle separation was successfully achieved using the following two different cases of particle mixtures: case 1) a mixture of 5-mum AS latex beads and 8-mum glass beads; and case 2) a mixture of ground pine (GP) spores and 8-mum glass beads. In case 1), 97% of the total AS beads were separated into one split droplet and 77% of the total glass beads into the other split droplet. In case 2), over 92% of the GP spores were separated into a split daughter droplet, whereas 86% of the glass beads were separated into the other split daughter droplet. In all these concentration and separation experiments, the applied frequency and the conductivity medium are key parameters influencing the concentration and separation performance, which have been optimally determined by measuring the DEP and electrorotation spectra of the used particles prior to the concentration and separation experiments. This integrated in-droplet separation and concentration method may provide an additional functionality to digital microfluidics.     

Stepwise gray-scale light-induced electric field gradient for passive and continuous separation of microparticles

This article presents a gray-scale light-induced dielectrophoresis (GS-LIDEP) method that induces the lateral displacements normal to the through-flow for continuous and passive separation of microparticles. In general, DEP force only can affect the particles within very local areas due to the electric field is exponentially decayed by the distance away from the electrodes. Unlike with conventional LIDEP, a broad-ranged electrical field gradient can easily be created by GS pattern illumination, which induces DEP forces with two directions for continuous separation of particles to their specific sub-channels. Candia albicans were effectively guided to the specific outlet with the efficiency of 90% to increase the concentration of the sample below the flow rate of 0.6?μl/min. 2 and 10?μm polystyrene particles can also be passively and well separated using the multi-step GS pattern through positive and negative DEP forces, respectively, under an applied voltage of 36?V_p–p at the frequency of 10?kHz. GS-LIDEP generated a wide-ranged DEP force that is capable of working on the entire area of the microchannel, and thus the mix of particles can be passively and continuously separated toward the opposite directions by the both positive and negative GS-LIDEP forces. This simple, low cost, and flexible separation/manipulation platform could be very promising for many applications, such as in-field detections/pretreatments.     

Dielectrophoretic separation of carbon nanotubes and polystyrene microparticles

The separation of multi-walled carbon nanotubes (MWCNTs) and polystyrene microparticles using a dielectrophoresis (DEP) system is presented. The DEP system consists of arrays of parallel microelectrodes patterned on a glass substrate. The performance of the system is evaluated by means of numerical simulations. The MWCNTs demonstrate a positive DEP behaviour and can be trapped at the regions of high electric field. However, the polystyrene microparticles demonstrate a negative DEP behaviour at a certain range of frequencies and migrate to the regions of low electric field. Experiments are performed on the microparticles at the frequencies between 100 Hz and 1 MHz to estimate their crossover frequency and select the range of separation frequencies. Further, experiments are conducted at the obtained range of separation frequencies to separate the MWCNTs and polystyrene microparticles.