High-Frequency Electronics for Contactless Dielectrophoresis

Caldwell, John Lawrence

16 June 2010

The field of sample enrichment is currently receiving a large amount of attention because it is essential to reduce the time required for many laboratory processes. Dielectrophoresis, or the motion of a polarized particle in the presence of a non-uniform electric field, has emerged as a promising method for biological sample concentration. By relying upon electrical properties that are intrinsic to a cell or microparticle, dielectrophoretic concentration avoids the need for sample preparation procedures which can greatly reduce the throughput of a system. Contactless Dielectrophoresis (cDEP) is a promising manifestation of dielectrophoresis in which the electrode structures that provide the non-uniform electric field are physically separated from the sample by a thin dielectric barrier. This work presents two methods for providing the high-voltage and high-frequency signal necessary to generate a non-uniform electric field in the sample channel of a cDEP device. The first method, an oscillator-based system, was able to produce DEP trapping and pearl-chaining of THP-1 and MCF-7 breast cancer cells in a cDEP device. The second method presented here utilizes an amplifier and transformer combination to generate very high voltages over a wide range of frequencies. Finally, electrorotation, or the spin imparted to a particle due to a rotating electric field has proven to be an extremely useful analysis of a cell's dielectric properties. A wideband, computer controlled function generator, outputting four sinusoidal waveforms in quadrature is presented. This device was able to produce outputs with the proper alignment over the range of 10 Hz to 100MHz. / Master of Science

Sample Enrichment

Dielectrophoresis

Electrorotation

A passive microfluidic device for continuous buffer exchange

Gedra, Olivia Rose

25 July 2024

Generally, dielectrophoresis (DEP) analysis of biological cell samples relies on the differing electrical parameters between the cells and the surrounding fluid medium. To achieve effective positive DEP manipulation and sorting of mammalian cells in suspension, it is required to resuspend the cells into a low-conductivity fluid buffer. The use of a low conductivity buffer also aids in minimizing the effects of Joule heating, which can cause cell death and ineffective cell trapping. The common method to prepare the sample relies on centrifugation of sensitive cells, a time-consuming and tedious process that may result in decreased sample viability. Herein is presented a microfluidic device that passively moves cells from a high-conductivity growth media into a low-conductivity DEP buffer. It is comprised of con- verging rows of pillars and uses mechanical filtration to force cells into the new buffer while allowing for the old fluid to flow through the posts and out of separate outlets. Because this device is intended to be used upstream of a contactless dielectrophoresis (cDEP) device, the buffer exchange device must have an outlet flow rate that is within the range necessary for direct integration with the cDEP device, maintain a low shear stress that will not affect the integrity of the sample and achieve sufficiently high cell recovery. Methods of this project included optimizing the shape, size, and orientation of the posts, determining the flow rate for maintaining an ideal DEP buffer conductivity, numerical modeling of shear stress, and determining the cell recovery rate. It is anticipated that this device can be extended to physiological media sample processing such as for liquid biopsy. / Master of Science / In order to accomplish numerous biomedical experiments, cells must be transferred from their native fluid growth media into a different fluid solution, through a process referred to as buffer exchange. The current method for buffer exchange is time consuming, tedious, and affects the number of cells left alive for experimentation. In this work, we present a microfluidic device that can accomplish the buffer exchange process by simply flowing in the cells in their media in parallel with the new buffer solution. The results of this research work can be extended to aid in the process of buffer exchange for various biological experiments. The proposed device utilizes mechanical filtration to force cells into the new buffer while allowing for the old fluid to flow through the posts and out of separate outlets. The design of the device was optimized through computational analysis of the concentration and fluid shear stress in conjunction with experimental tests of devices for outlet conductivity and cell retention.

Microfluidics

Buffer Exchange

Dielectrophoresis

Lab on a chip rare cell isolation platform with dielectrophoretic smart sample focusing, automated whole cell tracking analysis script, and a bioinspired on-chip electroactive polymer micropump

Anders, Lisa Mae

18 July 2014

Dielectrophoresis (DEP), an electrokinetic force, is the motion of a polarizable particle in a non-uniform electric field. Contactless DEP (cDEP) is a recently developed cell sorting and isolation technique that uses the DEP force by capacitavely coupling the electrodes across the channel. The cDEP platform sorts cells based on intrinsic biophysical properties, is inexpensive, maintains a sterile environment by using disposable chips, is a rapid process with minimal sample preparation, and allows for immediate downstream recovery. This platform is highly competitive compared to other cell sorting techniques and is one of the only platforms to sort cells based on phenotype, allowing for the isolation of unique cell populations not possible in other systems. The original purpose of this work was to determine differences in the bioelectrical fingerprint between several critical cancer types. Results demonstrate a difference between Tumor Initiating Cells, Multiple Drug Resistant Cells, and their bulk populations for experiments conducted on three prostate cancer cell lines and treated and untreated MOSE cells. However, three significant issues confounded these experiments and challenged the use of the cDEP platform. The purpose of this work then became the development of solutions to these barriers and presenting a more commercializable cDEP platform. An improved analysis script was first developed that performs whole cell detection and cell tracking with an accuracy of 93.5%. Second, a loading system for doing smart sample handling, specifically cell focusing, was developed using a new in-house system and validated. Experimental results validated the model and showed that cells were successfully focused into a tight band in the middle of the channel. Finally, a proof of concept for an on-chip micropump is presented and achieved 4.5% in-plane deformation. When bonded over a microchannel, fluid flow was induced and measured. These solutions present a stronger, more versatile cDEP platform and make for a more competitive commercial product. However, these solutions are not just limited to the cDEP platform and may be applicable to multitudes of other microfluidic devices and applications. / Master of Science

Dielectrophoresis

Contactless Dielectrophoresis

Lab on a Chip

Sample Enrichment

Tumor Initiating Cells

Higher Order Electrokinetic Effects for Applied Biological Analytics

January 2018

abstract: Microfluidic systems have gained popularity in the last two decades for their potential applications in manipulating micro- and nano- particulates of interest. Several different microfluidics devices have been built capable of rapidly probing, sorting, and trapping analytes of interest. Microfluidics can be combined with separation science to address challenges of obtaining a concentrated and pure distinct analyte from mixtures of increasingly similar entities. Many of these techniques have been developed to assess biological analytes of interest; one of which is dielectrophoresis (DEP), a force which acts on polarizable analytes in the presence of a non-uniform electric fields. This method can achieve high resolution separations with the unique attribute of concentrating, rather than diluting, analytes upon separation. Studies utilizing DEP have manipulated a wide range of analytes including various cell types, proteins, DNA, and viruses. These analytes range from approximately 50 nm to 1 µm in size. Many of the currently-utilized techniques for assessing these analytes are time intensive, cost prohibitive, and require specialized equipment and technical skills. The work presented in this dissertation focuses on developing and utilizing insulator-based dielectrophoresis (iDEP) to probe a wide range of analytes; where the intrinsic properties of an analyte will determine its behavior in a microchannel. This is based on the analyte’s interactions with the electrokinetic and dielectrophoretic forces present. Novel applications of this technique to probe the biophysical difference(s) between serovars of the foodborne pathogen, Listeria monocytogenes, and surface modified Escherichia coli, are investigated. Both of these applications demonstrate the capabilities of iDEP to achieve high resolution separations and probe slight changes in the biophysical properties of an analyte of interest. To improve upon existing iDEP strategies a novel insulator design which streamlines analytes in an iDEP device while still achieving the desirable forces for separation is developed, fabricated, and tested. Finally, pioneering work to develop an iDEP device capable of manipulating larger analytes, which range in size 10-250 µm, is presented. / Dissertation/Thesis / Doctoral Dissertation Chemistry 2018

Chemistry

Bioanalytics

Dielectrophoresis

Electrokinetics

Microfluidics

Electric Field Gradient and its Implications in Microfabricated Post Arrays

Kazemlou, Shokoufeh

Unknown Date

No description available.

Microfabricated Post Arrays

Electrophoresis

Dielectrophoresis

Electrical detection and actuation of single biological cells with application to deformability cytometry for markerless diagnostics

Ferrier, Graham

January 2003

An all-electrical system is developed to actuate and detect single biological cells in a microfluidic channel for diagnostic applications. Interdigitated electrodes fabricated on the channel floor transfer a high frequency signal for capacitance detection and a low frequency signal for dielectrophoretic actuation. In the fluid-filled channel, a pressure-driven flow propels single biological cells, which induce time-dependent capacitance signatures as they pass over the electrodes. With a sub-attofarad (~0.15 aF RMS, 53 Hz bandwidth) capacitance resolution, this system detects biological cells (e.g., 1 yeast cell ~ 50 aF) and their deflections (1 micrometer ~ 5 aF) from exerted dielectrophoretic forces (> 5 pN). Electrical detection of cell actuation by strong DEP forces provides an avenue for both inducing and monitoring the deformation of viscoelastic cells. A strong and repulsive dielectrophoretic force can be used to press a biological cell into a channel wall. When this occurs, the mechanical properties of the cell can be investigated by capacitively monitoring the cell-to-wall interaction. The nature of the resulting interaction is shown to depend on the mechanical properties of the cell (surface morphology and viscoelastic properties). Various mammalian cell types such as Chinese Hamster Ovary (CHO) cells, mouse fibroblasts, human blood cells, human breast cells and their tumorogenic phenotypes are investigated using this system. Between these populations, the effective Young's modulus varies widely from 20 Pa (neutrophils) to 1-2 GPa (polystyrene microspheres). The viability and phenotype of a biological cell are known to reflect its mechanical and electrical properties. Consequently, this work investigates whether dielectrophoretically induced cell deformations are correlated with corresponding variations in capacitance, which could be used for discriminating cell phenotypes in the future.

Dielectrophoresis

Capacitance

Deformability

Cytometry

Cells

Micro-scale Instruments Applied to a Bovine Nuclear Transfer System

Clow, Andrew Leif

January 2010

Manual handling of biological cells is routine in most laboratories. This is gradually changing with the development of robotic cell handling systems, and micro-scale lab-on-chip devices. Attempts were made to develop devices that automate or assist cell handling in the context of a bovine nuclear transfer (NT) system. The system, a zona-free bovine NT cloning system, formed a baseline reference for tool design and performance evaluation. Bovine NT can, as other cell handling procedures, be improved by rapid and precise cell positioning. Improvements in cell handling can increase the quantity of cells processed, and the uniformity of conditions the cells are subject to during processing. Tools were developed for two areas of cell handling: cell fusion and cell transportation. Designs suitable for implementation in microscale lab-on-chip systems were evaluated. Tool development was predominantly experimental, assisted by numerical modelling. The experimental investigation concerned device fabrication and operational performance. A number of cell handling tool designs were built and tested. Coplanar electrodes are not commonly used in bovine NT and reports on their efficacy were not available. These electrodes, which are simple to fabricate, were tested to determine fusion rates achievable in comparison with those of the baseline procedure. A novel fusion device, the micropit, was designed to assist bovine cell pairing and electrofusion. It was initially uncertain whether this device was capable of achieving cell fusion. Tests were conducted; and cell fusion and micro-positioning were demonstrated, as was an increase in biological cell processing throughput. Many miniaturised lab-on-chip systems rely on cell transportation. One illustration in the baseline procedure is the on-chip transport of cells to the cell fusion device. Potential cell transport mechanisms for a miniature cloning system were evaluated by prototype construction and testing. These mechanisms included travelling wave dielectrophoresis and capillary fluid actuation. To facilitate automation of on-chip cell transportation, a low cost electrically isolated cell detection system was developed based on a DVD pick-up unit. Various obstacles that were encountered during the course of device construction are noted, as are the fabrication methods employed.

Nuclear transfer

cloning

dielectrophoresis

electrofusion

Electrical detection and actuation of single biological cells with application to deformability cytometry for markerless diagnostics

Ferrier, Graham

January 2003

An all-electrical system is developed to actuate and detect single biological cells in a microfluidic channel for diagnostic applications. Interdigitated electrodes fabricated on the channel floor transfer a high frequency signal for capacitance detection and a low frequency signal for dielectrophoretic actuation. In the fluid-filled channel, a pressure-driven flow propels single biological cells, which induce time-dependent capacitance signatures as they pass over the electrodes. With a sub-attofarad (~0.15 aF RMS, 53 Hz bandwidth) capacitance resolution, this system detects biological cells (e.g., 1 yeast cell ~ 50 aF) and their deflections (1 micrometer ~ 5 aF) from exerted dielectrophoretic forces (> 5 pN). Electrical detection of cell actuation by strong DEP forces provides an avenue for both inducing and monitoring the deformation of viscoelastic cells. A strong and repulsive dielectrophoretic force can be used to press a biological cell into a channel wall. When this occurs, the mechanical properties of the cell can be investigated by capacitively monitoring the cell-to-wall interaction. The nature of the resulting interaction is shown to depend on the mechanical properties of the cell (surface morphology and viscoelastic properties). Various mammalian cell types such as Chinese Hamster Ovary (CHO) cells, mouse fibroblasts, human blood cells, human breast cells and their tumorogenic phenotypes are investigated using this system. Between these populations, the effective Young's modulus varies widely from 20 Pa (neutrophils) to 1-2 GPa (polystyrene microspheres). The viability and phenotype of a biological cell are known to reflect its mechanical and electrical properties. Consequently, this work investigates whether dielectrophoretically induced cell deformations are correlated with corresponding variations in capacitance, which could be used for discriminating cell phenotypes in the future.

Dielectrophoresis

Capacitance

Deformability

Cytometry

Cells

Microfluidic continuous separation of particles and cells by AC-dielectrophoresis

Çeti̇n, Barbaros,

January 2009

Thesis (Ph. D. in Mechanical Engineering)--Vanderbilt University, Aug. 2009. / Title from title screen. Includes bibliographical references.

Generation of Dielectrophoretic Force under Uniform Electric Field

Kua, C.H., Yang, C., Goh, S., Isabel, R., Youcef-Toumi, Kamal, Lam, Yee Cheong

01 1900

Effective dipole moment method has been widely accepted as the de facto technique in predicting the dielectrophoretic force due to the non-uniform electric field. In this method, a finite-particle is modeled as an equivalent point-dipole that would induce a same electric field under the external electric field. This approach is only valid when the particle size is significantly smaller than the characteristic length of interest. This assumption is often violated in a microfluidic device, where the thickness or width of the microchannel can be as small as the particle. It is shown in this numerical study that when the dimensions of the particle were in the same order of magnitude as the characteristic length of the device, dielectrophoretic force can be induced even in a uniform electric field. This force arises due to the disturbance of the particle and the bounding wall. / Singapore-MIT Alliance (SMA)

electrostatic force

dipole moment

dielectrophoresis