Integrated Microfluidic Flow Sensor for LAB-oN-CHIP and PoINT-oF-CARE Applications

The results of the development and manufacture of an integrated membrane-free sensor for the control of accurate dilution of liquid samples on the microfluidic chip are presented. The proposed type of devices is intended for direct precise measurements of liquid flow rate in microchannels of laboratories-on-chip, including point-of-care systems. The sensor topology was optimized based on the numerical simulation results and technological requirements. The main characteristic of the developed sensor is the lack of a membrane in the design while maintaining the sensitivity and accuracy of the device at the level of a commercial membrane analogue. The fully biocompatible sensor was manufactured using standard microelectronics and soft lithography technologies. In order to optimize the sensor design, 32 different topologies of the device were tested. The integration of the flow sensors on the chip allows to significantly reduce the dead volume of the hydrodynamic system and to control the amount of liquid entering the individual reservoirs of the microfluidic chip. The sensor occupies an area of (210 x 140) um2 in the channel and is characterized by a relative error of 5% in the flow rate range of 100-1000 ul/min. microfluidics, lab-on-chip, calorimetric flow sensor, thermoresistive sensor, numerical simulation, hydrodynamics, complementary metal-oxide-semiconductor, microtechnologies Devices were made at the BMSTU Nanofabrication Facility (FMN Laboratory, FMNS REC, ID 74300).

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INTEGRATED MICROFLUIDIC FLOW SENSOR FOR LAB-ON-CHIP AND POINT-OF-CARE APPLICATIONS

BIOTECHNOLOGY: STATE OF THE ART AND PERSPECTIVES ◽

10.37747/2312-640x-2020-18-457-458 ◽

2020 ◽

pp. 457-458

Author(s):

V. Ryzhkov ◽

M. Andronik ◽

V. Echeistov ◽

Z. Issabayeva ◽

O. Sorokina ◽

...

Keyword(s):

Microfluidic Chip ◽

Point Of Care ◽

Experimental Comparison ◽

Fluid Flow Rate ◽

Fabrication Technology ◽

Flow Sensors ◽

Lab On Chip ◽

Microfluidic Flow ◽

Chip Fabrication ◽

On Chip

An integrated membrane-free sensor for precise measurements of fluid flow rate in microchannels of laboratories-on- chip has been developed. The sensor allows to measure flow on microfluidic chip in real time and is designed for liquid samples precise dilution control on the microfluidic chip. Fabrication technology of the microfluidic chip with built-in flow sensors as well as results of experimental comparison of developed sensor with a commercial flowmeter are presented.

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Design and Fabrication of Multichannel PDMS Microfluidic

Journal of Physics Conference Series ◽

10.1088/1742-6596/2129/1/012048 ◽

2021 ◽

Vol 2129 (1) ◽

pp. 012048

Author(s):

M N Afnan Uda ◽

U Hashim ◽

M N A Uda ◽

N A Parmin ◽

V Thivina

Keyword(s):

Contact Area ◽

Microfluidic Chip ◽

Point Of Care ◽

Main Tool ◽

Morphological Properties ◽

Single Chip ◽

Lab On Chip ◽

Micro Channels ◽

On Chip ◽

Disease Analysis

Abstract Microfluidic delivers miniaturized fluidic networks for processing liquids in the microliter range. In the recent years, lab-on-chip (LOC) is become a main tool for point-of-care (POC) diagnostic especially in the medical field. In this paper, we presented a design and fabrication on multi disease analysis using single chip via delivery of fluid with the multiple transducers is the pathway of multi-channel microfluidic based LOC’s. 3 in 1 nano biosensor kit was attached with the microfluidic to produce nano-biolab-on-chip (NBLOC). The multi channels microfluidic chip was designed including the micro channels, one inlet, three outlet and sensor contact area. The microfluidic chip was designed to include multiplex detection for pathogen that consists of multiple channels of simultaneous results. The LOC system was designed using Design Spark Mechanical software and PDMS was used as a medium of the microfluidic. The microfluidic mold and PDMS microfluidic morphological properties have been characterized by using low power microscope (LPM), high power microscope (HPM) and surface profiler. The LOC system physical was experimental by dropping food coloring through the inlet and collecting at the sensor contact area outlet.

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Quantitative and rapid Plasmodium falciparum malaria diagnosis and artemisinin-resistance detection using a CMOS Lab-on-Chip platform

10.1101/638221 ◽

2019 ◽

Cited By ~ 1

Author(s):

K. Malpartida-Cardenas ◽

N. Miscourides ◽

J. Rodriguez-Manzano ◽

L. S. Yu ◽

J. Baum ◽

...

Keyword(s):

Field Effect Transistors ◽

Point Of Care ◽

Artemisinin Resistance ◽

Diagnostic Methods ◽

Nucleic Acid Amplification ◽

Optical Measurements ◽

Oxide Semiconductor ◽

Analytical Sensitivity ◽

Lab On Chip ◽

On Chip

AbstractEarly and accurate diagnosis of malaria and drug-resistance is essential to effective disease management. Available rapid malaria diagnostic tests present limitations in analytical sensitivity, drug-resistant testing and/or quantification. Conversely, diagnostic methods based on nucleic acid amplification stepped forwards owing to their high sensitivity, specificity and robustness. Nevertheless, these methods commonly rely on optical measurements and complex instrumentation which limit their applicability in resource-poor, point-of-care settings. This paper reports the specific, quantitative and fully-electronic detection of Plas-modium falciparum, the predominant malaria-causing parasite worldwide, using a Lab-on-Chip platform developed in-house. Furthermore, we demonstrate on-chip detection of C580Y, the most prevalent single-nucleotide polymorphism associated to artemisinin-resistant malaria. Real-time non-optical DNA sensing is facilitated using Ion-Sensitive Field-Effect Transistors, fabricated in unmodified complementary metal-oxide-semiconductor technology, coupled with loop-mediated isothermal amplification. This work holds significant potential for the development of a fully portable and quantitative malaria diagnostic that can be used as a rapid point-of-care test.

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Integrated Magnetohydrodynamic Pump with Magnetic Composite Substrate and Laser-Induced Graphene Electrodes

Polymers ◽

10.3390/polym13071113 ◽

2021 ◽

Vol 13 (7) ◽

pp. 1113

Author(s):

Mohammed Asadullah Khan ◽

Jürgen Kosel

Keyword(s):

Magnetic Flux ◽

Flow Rate ◽

Magnetic Composite ◽

Propulsive Force ◽

Closed Channel ◽

Lab On Chip ◽

Composite Substrate ◽

On Chip ◽

High Level ◽

Moving Parts

An integrated polymer-based magnetohydrodynamic (MHD) pump that can actuate saline fluids in closed-channel devices is presented. MHD pumps are attractive for lab-on-chip applications, due to their ability to provide high propulsive force without any moving parts. Unlike other MHD devices, a high level of integration is demonstrated by incorporating both laser-induced graphene (LIG) electrodes as well as a NdFeB magnetic-flux source in the NdFeB-polydimethylsiloxane permanent magnetic composite substrate. The effects of transferring the LIG film from polyimide to the magnetic composite substrate were studied. Operation of the integrated magneto hydrodynamic pump without disruptive bubbles was achieved. In the studied case, the pump produces a flow rate of 28.1 µL/min. while consuming ~1 mW power.

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Point-of-Care Systems for Rapid DNA Quantification in Oncology

Tumori Journal ◽

10.1177/030089160809400214 ◽

2008 ◽

Vol 94 (2) ◽

pp. 216-225 ◽

Cited By ~ 5

Author(s):

Marco Bianchessi ◽

Sarah Burgarella ◽

Marco Cereda

Keyword(s):

Point Of Care ◽

Low Cost ◽

Semiconductor Industry ◽

Point Of Care Testing ◽

Lab On Chip ◽

Diagnostic Assays ◽

Care Systems ◽

Point Of Care Systems ◽

The Common ◽

On Chip

The development of new powerful applications and the improvement in fabrication techniques are promising an explosive growth in lab-on-chip use in the upcoming future. As the demand reaches significant levels, the semiconductor industry may enter in the field, bringing its capability to produce complex devices in large volumes, high quality and low cost. The lab-on-chip concept, when applied to medicine, leads to the point-of-care concept, where simple, compact and cheap instruments allow diagnostic assays to be performed quickly by untrained personnel directly at the patient's side. In this paper, some practical and economical considerations are made to support the advantages of point-of-care testing. A series of promising technologies developed by STMicroelectronics on lab-on-chips is also presented, mature enough to enter in the common medical practice. The possible use of these techniques for cancer research, diagnosis and treatment are illustrated together with the benefits offered by their implementation in point-of-care testing.

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Multistage Isoelectric Focusing: A Novel On-Chip Bio-Separation Technique

Fluids Engineering ◽

10.1115/imece2005-79978 ◽

2005 ◽

Author(s):

Prashanta Dutta ◽

Keisuke Horiuchi ◽

Huanchun Cui ◽

Cornelius F. Ivory

Keyword(s):

Isoelectric Focusing ◽

Microfluidic Chip ◽

Soft Lithography ◽

Fluorescent Protein ◽

Ph Gradient ◽

Resolving Power ◽

Protein Species ◽

Second Stage ◽

On Chip ◽

Bonding Technique

This experimental study reports a method to increase the resolving power of isoelectric focusing (IEF) on a polymeric microfluidic chip. Microfluidic chip is formed on poly-di-methyl siloxane (PDMS) using soft lithography and multilayer bonding technique. In this novel bioseparation technique, IEF is staged by first focusing protein species in a straight channel using broad-range ampholytes and then refocusing segments of that first channel into secondary channels that branch out from the first one. Experiments demonstrated that three fluorescent protein species within a segment of pH gradient in the first stage were refocused in the second stage with much higher resolution in a shallower pH gradient. A serially performed two-stage IEF was completed in less than 25 minutes under particularly small electric field strength up to 100 V/cm.

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From CAD to microfluidic chip within one day: rapid prototyping of lab-on-chip cartridges using generic polymer parts

Journal of Micromechanics and Microengineering ◽

10.1088/1361-6439/aba5dd ◽

2020 ◽

Vol 30 (11) ◽

pp. 115012 ◽

Cited By ~ 1

Author(s):

Daniel Podbiel ◽

Lorenz Boecking ◽

Hannah Bott ◽

Julian Kassel ◽

Daniel Czurratis ◽

...

Keyword(s):

Rapid Prototyping ◽

Microfluidic Chip ◽

Lab On Chip ◽

On Chip

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Rapid and portable, lab-on-chip, point-of-care genotyping for evaluating clopidogrel metabolism

Clinica Chimica Acta ◽

10.1016/j.cca.2015.10.003 ◽

2015 ◽

Vol 451 ◽

pp. 240-246 ◽

Cited By ~ 17

Author(s):

Nicola Marziliano ◽

Maria Francesca Notarangelo ◽

Marco Cereda ◽

Vittoria Caporale ◽

Lucia Coppini ◽

...

Keyword(s):

Point Of Care ◽

Lab On Chip ◽

On Chip

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Fast, accurate, point-of-care COVID-19 pandemic diagnosis enabled through advanced lab-on-chip optical biosensors: Opportunities and challenges

Applied Physics Reviews ◽

10.1063/5.0022211 ◽

2021 ◽

Vol 8 (3) ◽

pp. 031313

Author(s):

Aref Asghari ◽

Chao Wang ◽

Kyoung Min Yoo ◽

Ali Rostamian ◽

Xiaochuan Xu ◽

...

Keyword(s):

Point Of Care ◽

Optical Biosensors ◽

Lab On Chip ◽

On Chip

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Micro–Macro: Selective Integration of Microfeatures Inside Low-Cost Macromolds for PDMS Microfluidics Fabrication

Micromachines ◽

10.3390/mi10090576 ◽

2019 ◽

Vol 10 (9) ◽

pp. 576 ◽

Cited By ~ 1

Author(s):

Edgar Jiménez-Díaz ◽

Mariel Cano-Jorge ◽

Diego Zamarrón-Hernández ◽

Lucia Cabriales ◽

Francisco Páez-Larios ◽

...

Keyword(s):

Soft Lithography ◽

Low Cost ◽

Cost Effective ◽

Microfluidic Chips ◽

Single Chip ◽

Lab On Chip ◽

Molding Method ◽

On Chip ◽

Selective Integration ◽

Important Progress

Microfluidics has become a very promising technology in recent years, due to its great potential to revolutionize life-science solutions. Generic microfabrication processes have been progressively made available to academic laboratories thanks to cost-effective soft-lithography techniques and enabled important progress in applications like lab-on-chip platforms using rapid- prototyping. However, micron-sized features are required in most designs, especially in biomimetic cell culture platforms, imposing elevated costs of production associated with lithography and limiting the use of such devices. In most cases, however, only a small portion of the structures require high-resolution and cost may be decreased. In this work, we present a replica-molding method separating the fabrication steps of low (macro) and high (micro) resolutions and then merging the two scales in a single chip. The method consists of fabricating the largest possible area in inexpensive macromolds using simple techniques such as plastics micromilling, laser microfabrication, or even by shrinking printed polystyrene sheets. The microfeatures were made on a separated mold or onto existing macromolds using photolithography or 2-photon lithography. By limiting the expensive area to the essential, the time and cost of fabrication can be reduced. Polydimethylsiloxane (PDMS) microfluidic chips were successfully fabricated from the constructed molds and tested to validate our micro–macro method.

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