A novel alternating current multiple array electrothermal micropump for lab-on-a-chip applications

Salari, Alinaghi; Navi, Maryam; Dalton, Colin

doi:10.1063/1.4907673

Cited by 62 publications

(72 citation statements)

References 39 publications

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“…Free charges move in the nonuniform electric field, which exerts body force on the fluid to generate ACET flow. 32 When an electric field distribution occurs throughout the fluid region, Joule heating of the fluid can be expressed by the energy balance equation 36,38 …”

Section: Acet Theorymentioning

confidence: 99%

“…The cell culture medium was pumped by an ACET asymmetric electrode array, while two types of human cells, embryonic kidney (HEK293T) and colon carcinoma (SW620), grew well in the device for more than 72 h without experiencing Joule heating from ACET flow or electrical damage from the electrodes. This is a conventional asymmetric electrode array where ACET flow moves from the narrow electrode toward the broad one 26,36 ( Fig. 1(a)).…”

Section: Introductionmentioning

confidence: 99%

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In-plane microvortices micromixer-based AC electrothermal for testing drug induced death of tumor cells

et al. 2016

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Herein, we first describe a perfusion chip integrated with an AC electrothermal (ACET) micromixer to supply a uniform drug concentration to tumor cells. The inplane fluid microvortices for mixing were generated by six pairs of reconstructed novel ACET asymmetric electrodes. To enhance the mixing efficiency, the novel ACET electrodes with rotating angles of 0 , 30 , and 60 were investigated. The asymmetric electrodes with a rotating angle of 60 exhibited the highest mixing efficiency by both simulated and experimental results. The length of the mixing area is 7 mm, and the mixing efficiency is 89.12% (approximate complete mixing) at a voltage of 3 V and a frequency of 500 kHz. The applicability of our micromixer with electrodes rotating at 60 was demonstrated by the drug (tamoxifen) test of human breast cancer cells (MCF-7) for five days, which implies that our ACET inplane microvortices micromixer has great potential for the application of drug induced rapid death of tumor cells and mixing of biomaterials in organs-on-a-chip systems. Published by AIP Publishing. [http://dx

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Section: Acet Theorymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

In-plane microvortices micromixer-based AC electrothermal for testing drug induced death of tumor cells

et al. 2016

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“…However, increasing the frequencies to higher values (>10 5 kHz) can affect the electrothermal force 3 . The simulation method was verified by comparing one combination of the aforementioned parameters to the data obtained from our previously fabricated ACET micropumps 1,5,19 . The electrode arrays were fabricated on glass and silicon by photolithography and the fluidic microchannel was made from PDMS.…”

Section: Effect Of Actuation Frequencymentioning

confidence: 99%

Fluid flow study of an AC electrothermal micropump consisting of multiple arrays of microelectrodes for biofluidic applications

Salari

Dalton

2015

SPIE Proceedings

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Electrokinetics has many applications in a wide range of areas, such as lab-on-a-chip and biomedical microdevices. The electrothermal effect has been used for biofluid delivery systems since it has high pumping efficiency for high conductive liquids (>0.1 S/m) compared to other electrokinetic techniques such as electroosmosis. AC electrothermal (ACET) micropumps are based on the temperature gradient caused by Joule heating or an external heat source, which generates permittivity and conductivity gradients in the bulk of the liquid. When the liquid is subjected to an electric field, the ACET force is created. Electrode geometry significantly affects the electric field distribution, which can yield stronger ACET forces. Previously electrode dimension optimization has been performed for a single-array coplanar asymmetric configuration in order to obtain maximum ACET velocities. In this paper we expand the study to other governing parameters in a multiple-row microelectrode array configuration consisting of microelectrodes placed on top, bottom , and/or side walls of a microchannel. The studied parameters are the substrate material and thickness , ambient temperature, fluid viscosity, and actuation frequency. Electrode dimensions remain constant during the study (120 µm wide and 20 µm thin electrodes, 20 µm gap). The study is performed using finite element analysis software for one pair of microelectrodes on each array with periodic boundary conditions. The simulation data is then compared with experimental data for a single combination of the aforementioned parameters. The results show that the effect of these parameters on ACET flow can be significant.

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“…Micropumps are becoming increasingly important for a wide range of applications, such as, pharmaceutical and bio-medical drug delivery systems, serving as micro-fluid flow control appliance for analyzing systems for chemical and biological substances [1][2][3] . Because micropumps have the unique ability to deliver an accurate amount of liquid, many different types of micropumps have been developed using several actuation methods such as, electrostatic, piezoelectric, thermopneumatic, electrochemical, shape memory alloy(SMA), and electromagnetic [4] .…”

Section: Introduction mentioning

confidence: 99%

Effects of driving mode on the performance of multiple-chamber piezoelectric pumps with multiple actuators

Zhang

Kan

Wang

et al. 2015

Chin. J. Mech. Eng.

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Due to the limited output capability of piezoelectric diaphragm pumps, the driving voltage is frequently increased to obtain the desired output. However, the excessive voltage application may lead to a large deformation in the piezoelectric ceramics, which could cause it to breakdown or become damaged. Therefore, increasing the number of chambers to obtain the desired output is proposed. Using a check-valve quintuple-chamber pump with quintuple piezoelectric actuators, the characteristics of the pump under different driving modes are investigated through experiments. By changing the number and connection mode of working actuators, pump performances in terms of flow rate and backpressure are tested at a voltage of 150 V with a frequency range of 60 Hz 400 Hz. Experiment results indicate that the properties of the multiple-chamber pump change significantly with distinct working chambers even though the number of pumping chambers is the same. Pump performance declines as the distance between the working actuators increases. Moreover, pump performance declines dramatically when the working piezoelectric actuator closest to the outlet is involved. The maximum backpressures of the pump with triple, quadruple, and quintuple actuators are increased by 39%, 83%, and 128%, respectively, compared with the pump with double working actuators; the corresponding maximum flow rates of the pumps are simply increased by 25.9%, 49.2%, and 67.8%, respectively. The proposed research offers practical guidance for the effective utilization of the multiple-chamber pumps under different driving modes.

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A novel alternating current multiple array electrothermal micropump for lab-on-a-chip applications

Cited by 62 publications

References 39 publications

In-plane microvortices micromixer-based AC electrothermal for testing drug induced death of tumor cells

In-plane microvortices micromixer-based AC electrothermal for testing drug induced death of tumor cells

Fluid flow study of an AC electrothermal micropump consisting of multiple arrays of microelectrodes for biofluidic applications

Effects of driving mode on the performance of multiple-chamber piezoelectric pumps with multiple actuators

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