Piezoresistive Conductive Microfluidic Membranes for Low-Cost On-Chip Pressure and Flow Sensing

10.20944/preprints202112.0410.v2 ◽

2022 ◽

Author(s):

Md Nazibul Islam ◽

Steven M Doria ◽

Zachary R Gagnon ◽

Xiaotong Fu

Keyword(s):

Time Pressure ◽

Low Cost ◽

Fluid Pressure ◽

Fluid Flows ◽

Microfluidic Devices ◽

Microfluidic Channels ◽

Impedance Change ◽

Conductive Membranes ◽

Chip Fabrication ◽

On Chip

Over the last two decades, microfluidics has received significant attention from both academia and industry, and researchers report thousands of new prototype devices each year for use in a broad range of environmental, pharmaceutical, and biomedical engineering applications. While lab-on-a-chip fabrication costs have continued to decrease, the hardware required for monitoring fluid flows within microfluidic devices themselves remains expensive and often cost prohibitive for researchers interested in starting a microfluidics project. As microfluidic devices become capable of handling complex fluidic systems, low-cost, precise and real time pressure and flow rate measurement capabilities has become increasingly important. While many labs use commercial platforms and sensor, these solutions can often cost thousands of dollars and can be too bulky for on-chip use. Here we present a new inexpensive and easy -to-use piezoresistive pressure and flow sensor that can be easily integrated into existing on-chip microfluidic channels. The sensor consists of PDMS-Carbon black conductive membranes and uses an impedance analyzer to measure impedance change due fluid pressure. The sensor costs several orders of magnitude less than existing commercial platforms and can monitor local fluid pressures and calculate flow rates based on pressure gradient.

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On-Chip Fabrication of None-Dead-Volume Microtips for ESI-MS Applications

Solid State Phenomena ◽

10.4028/www.scientific.net/ssp.121-123.611 ◽

2007 ◽

Vol 121-123 ◽

pp. 611-614

Author(s):

Che Hsin Lin ◽

Jen Taie Shiea ◽

Yen Lieng Lin

Keyword(s):

Surface Tension ◽

Low Cost ◽

Microfluidic Channel ◽

Dead Volume ◽

Esi Ms ◽

Rapid Fabrication ◽

Chip Fabrication ◽

Novel Method ◽

On Chip ◽

Highly Uniform

This paper proposes a novel method to on-chip fabricate a none-dead-volume microtip for ESI-MS applications. The microfluidic chip and ESI tip are fabricated in low-cost plastic based materials using a simple and rapid fabrication process. A constant-speed-pulling method is developed to fabricate the ESI tip by pulling mixed PMMA glue using a 30-μm stainless wire through the pre-formed microfluidic channel. The equilibrium of surface tension of PMMA glue will result in a sharp tip after curing. A highly uniform micro-tip can be formed directly at the outlet of the microfluidic channel with minimum dead-volume zone. Detection of caffeine, myoglobin, lysozyme and cytochrome C biosamples confirms the microchip device can be used for high resolution ESI-MS applications.

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On–Chip Droplets Sensing using Capacitive Technique

Jurnal Teknologi ◽

10.11113/jt.v61.1641 ◽

2013 ◽

Vol 61 (2) ◽

Author(s):

Mohamad Faizal Abdullah ◽

P. L. Leow ◽

M. A. Abd Razak ◽

F. K. Che Harun

Keyword(s):

Low Cost ◽

Microfluidic Channel ◽

High Sensitivity ◽

Microfluidic Devices ◽

Capacitive Sensor ◽

Sample Volume ◽

Microfluidic System ◽

Coplanar Electrodes ◽

On Chip ◽

Significant Attention

Significant attention has been given on the development of droplets–based microfluidic system because of its potential and apparent advantages. Beside the advantages of reducing the sample volume, it’s also offer less time consuming for the analysis. Optical and fluorescence among the famous method that was used in detection of droplets but they are normally bulky, expensive and not easily accessed. This paper proposed a simple, low cost and high sensitivity for droplets sensing in microfluidic devices by using capacitive sensor. Coplanar electrodes are used to form a capacitance through the microfluidic channel. The design of eight pair of electrodes was used to detect the presence of a droplet. Changes in capacitance due to the presence of a droplet in the sensing area is detected and used to trigger the microscope to capture the image of detected droplets in microchannel. The measurement of droplets detected and counting are displayed through a LABVIEW interface in the real time.

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High-throughput acoustofluidic microchannels for single cell rotation

Journal of Micromechanics and Microengineering ◽

10.1088/1361-6439/ac349e ◽

2021 ◽

Author(s):

Junwen Zhu ◽

Qiqian Zhang ◽

Fei Liang ◽

Yongxiang Feng ◽

Wenhui Wang

Keyword(s):

High Throughput ◽

Low Cost ◽

Rotation Velocity ◽

Microfluidic Channels ◽

Lab On Chip ◽

Dead End ◽

Cell Rotation ◽

Fabrication Procedure ◽

On Chip ◽

Highly Uniform

Abstract There is a growing desire for cell rotation in the field of biophysics, bioengineering and biomedicine. We herein present novel microfluidic channels for simultaneous high-throughput cell self-rotation using local circular streaming generated by ultrasonic wave excited bubble arrays. The bubble traps achieve high homogeneity of liquid-gas interface by setting capillary valves at the entrances of dead-end bubble trappers orthogonal to the main microchannel. In such a highly uniform bubble array, rotation at different fields of bubble-relevant vortices is considered equal and interconvertible. The device is compatible with cells of various size and retains manageable rotation velocity when actuated by signals of varying frequency and voltage. Experimental observations were confirmed consistent with theoretical estimation and numerical simulation. Comparing with the conventional approaches of cell rotation, our device has multiple merits such as high throughput, low cost and simple fabrication procedure, and high compatibility for lab-on-chip integration. Therefore, the platform holds a promise in cell observation, medicine development and biological detection.

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A Low-Cost, Rapidly Integrated Debubbler (RID) Module for Microfluidic Cell Culture Applications

Micromachines ◽

10.3390/mi10060360 ◽

2019 ◽

Vol 10 (6) ◽

pp. 360 ◽

Cited By ~ 1

Author(s):

Matthew J. Williams ◽

Nicholas K. Lee ◽

Joseph A. Mylott ◽

Nicole Mazzola ◽

Adeel Ahmed ◽

...

Keyword(s):

Mammalian Cells ◽

Cultured Cells ◽

Cell Damage ◽

Removal Rate ◽

Low Cost ◽

Fluid Flows ◽

Microfluidic Channels ◽

Air Bubbles ◽

Experimental Systems ◽

Microfluidic Cell Culture

Microfluidic platforms use controlled fluid flows to provide physiologically relevant biochemical and biophysical cues to cultured cells in a well-defined and reproducible manner. Undisturbed flows are critical in these systems, and air bubbles entering microfluidic channels can lead to device delamination or cell damage. To prevent bubble entry into microfluidic channels, we report a low-cost, Rapidly Integrated Debubbler (RID) module that is simple to fabricate, inexpensive, and easily combined with existing experimental systems. We demonstrate successful removal of air bubbles spanning three orders of magnitude with a maximum removal rate (dV/dt)max = 1.5 mL min−1, at flow rates required to apply physiological wall shear stress (1–200 dyne cm−2) to mammalian cells cultured in microfluidic channels.

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Low-cost microphysiological systems: Feasibility study of a tape-based barrier-on-chip system for small intestine modeling

10.1101/2020.01.06.894147 ◽

2020 ◽

Author(s):

Thomas E. Winkler ◽

Michael Feil ◽

Eva F.G.J. Stronkman ◽

Isabelle Matthiesen ◽

Anna Herland

Keyword(s):

Small Intestine ◽

Pore Size ◽

Biological Effects ◽

Low Cost ◽

Adhesive Tape ◽

Pressure Sensitive Adhesive ◽

Laboratory Equipment ◽

Chip Fabrication ◽

On Chip ◽

Permeable Support

AbstractWe see affordability as a key challenge in making organs-on-chips accessible to a wider range of users, particularly outside the highest-resource environments. Here, we present an approach to barrier-on-a-chip fabrication based on double-sided pressure-sensitive adhesive tape and off-the-shelf polycarbonate. Besides a low materials cost, common also to PDMS or thermoplastics, it requires minimal (€ 100) investment in laboratory equipment, yet at the same time is suitable for upscaling to industrial roll-to-roll manufacture. We evaluate our microhpysiological system with an epithelial (C2BBe1) barrier model of the small intestine, studying the biological effects of permeable support pore size, as well as stimulation with a common food compound (chili pepper-derived capsaicinoids). The cells form tight and continuous barrier layers inside our systems, with comparable permeability but superior epithelial polarization compared to Transwell culture, in line with other perfused microphysiological models. Permeable support pore size is shown to weakly impact barrier layer integrity as well as the metabolic cell profile. Capsaicinoid response proves distinct between culture systems, but we show that impacted metabolic pathways are partly conserved, and that cytoskeletal changes align with previous studies. Overall, our tape-based microphysiolgical system proves to be a robust and reproducible approach to studying physiological barriers, in spite of its low cost.

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Laminate Materials for Microfluidic PCBs

International Symposium on Microelectronics ◽

10.4071/isom-2012-ta54 ◽

2012 ◽

Vol 2012 (1) ◽

pp. 000162-000168

Author(s):

Sarkis Babikian ◽

Brian Soriano ◽

G.P. Li ◽

Mark Bachman

Keyword(s):

Printed Circuit Board ◽

Low Cost ◽

Microfluidic Devices ◽

Ethylene Vinyl Acetate ◽

Circuit Board ◽

Microfluidic Channels ◽

Printed Circuit ◽

Laminate Materials ◽

Integrated Microfluidics ◽

Functional Components

The printed circuit board (PCB) is a very attractive platform to produce highly integrated highly functional microfluidic devices. We have investigated laminate materials and developed novel fabrication processes to realize low cost and scalable to manufacturing integrated microfluidics on PCBs. In this paper we describe our vision to integrate functional components with microfluidic channels. We also report on the use of Ethylene Vinyl Acetate (EVA) as a laminate for microfluidics. The material was characterized for microfluidic applications and compared with our previously reported laminates: 1002F and Polyurethane.

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Low-cost, widespread and reproducible mold fabrication technique for PDMS-based microfluidic photonic systems

Photonics Letters of Poland ◽

10.4302/plp.v12i1.981 ◽

2020 ◽

Vol 12 (1) ◽

pp. 22

Author(s):

Szymon Baczyński ◽

Piotr Sobotka ◽

Kasper Marchlewicz ◽

Artur Dybko ◽

Katarzyna Rutkowska

Keyword(s):

Low Cost ◽

Lab On A Chip ◽

Microfluidic Devices ◽

Optical Quality ◽

Microfluidic Channels ◽

Nanosecond Laser ◽

Microfluidic Systems ◽

Optical Mems ◽

Technical Data ◽

Mold Fabrication

In this letter the possibility of low-cost fabrication of molds for PDMS-based photonic microstructures is considered. For this purpose, three different commercially available techniques, namely UV-curing of the capillary film, 3D SLA printing and micromilling, have been analyzed. Obtained results have been compared in terms of prototyping time, quality, repeatability, and re-use of the mold for PDMS-based microstructures fabrication. Prospective use for photonic systems, especially optofluidic ones infiltrated with liquid crystalline materials, have been commented. Full Text: PDF References:K. Sangamesh, C.T. Laurencin, M. Deng, Natural and Synthetic Biomedical Polymers (Elsevier, Amsterdam 2004). [DirectLink]A. Mata et. al, "Characterization of Polydimethylsiloxane (PDMS) Properties for Biomedical Micro/Nanosystems", Biomed. Microdev. 7(4), 281 (2005). [CrossRef]I. Rodríguez-Ruiz et al., "Photonic Lab-on-a-Chip: Integration of Optical Spectroscopy in Microfluidic Systems", Anal. Chem. 88(13), 6630 (2016). [CrossRef]SYLGARD™ 184 Silicone Elastomer, Technical Data Sheet [DirectLink]N.E. Stankova et al., "Optical properties of polydimethylsiloxane (PDMS) during nanosecond laser processing", Appl. Surface Science 374, 96 (2016) [CrossRef]J.C. McDonald et al., "Fabrication of microfluidic systems in poly(dimethylsiloxane)", Electrophoresis 21(1), 27 (2000). [CrossRef]T. Fujii, "PDMS-based microfluidic devices for biomedical applications", Microelectronic Eng. 61, 907 (2002). [CrossRef]F. Schneider et al., "Process and material properties of polydimethylsiloxane (PDMS) for Optical MEMS", Sensors Actuat. A: Physical 151(2), 95 (2009). [CrossRef]T.K. Shih et al., "Fabrication of PDMS (polydimethylsiloxane) microlens and diffuser using replica molding", Microelectronic Eng. 83(11-12), 2499 (2006). [CrossRef]K. Rutkowska et al. "Electrical tuning of the LC:PDMS channels", PLP, 9, 48-50 (2017). [CrossRef]D. Kalinowska et al., "Studies on effectiveness of PTT on 3D tumor model under microfluidic conditions using aptamer-modified nanoshells", Biosensors Bioelectr. 126, 214 (2019).[CrossRef]N. Bhattacharjee et al., "The upcoming 3D-printing revolution in microfluidics", Lab on a Chip 16(10), 1720 (2016). [CrossRef]I.R.G. Ogilvie et al., "Reduction of surface roughness for optical quality microfluidic devices in PMMA and COC", J. Micromech. Microeng. 20(6), 065016 (2010). [CrossRef]D. Gomez et al., "Femtosecond laser ablation for microfluidics", Opt. Eng. 44(5), 051105 (2005). [CrossRef]Y. Hwang, R.N. Candler, "Non-planar PDMS microfluidic channels and actuators: a review", Lab on a Chip 17(23), 3948 (2017). [CrossRef]

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