Integration of Ultra-Low Volume Pneumatic Microfluidics with a Three-Dimensional Electrode Network for On-Chip Biochemical Sensing

Tomar, Saurabh; Lasne, Charlotte; Barraud, S.; Ernst, T.; Guiducci, Carlotta

doi:10.3390/mi12070762

Cited by 2 publications

(2 citation statements)

References 36 publications

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“…Utilizing the physical phenomenon at the microscale, the time and energy efficiency of biochemical reactions could be greatly improved. The excellent compatibility of microfluidics in electromechanical control, medical science and biochemical reactions can also provide a significant possibility for minimizing reaction devices [3][4][5][6][7]. Following advances in techniques and the increase in demand, multiform microfluidic devices have been invented and adopted.…”

Section: Introductionmentioning

confidence: 99%

“…For the spatially cycled protocol, the temperature at each area is fixed and the reaction solution flows through different temperature zones in turn. The solution could be driven by external pressure in a serpentine channel [7,18], a radial channel [33] or a spiral channel [25]; by integrated pneumatic micro pumps [8], ferro-fluidic plugs [34] or a magnetized ball pressing on a loop channel [35] with a rotating guiding magnet beneath; and by Rayleigh-Bénard convection in a cylindrical cavity [29]. For the temporally cycled protocol, the reaction solution is stationary while the temperature at the entire reaction zone changes over time.…”

Section: Introductionmentioning

confidence: 99%

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Thermodynamic Characterization of a Highly Transparent Microfluidic Chip with Multiple On-Chip Temperature Control Units

Yang

Wang

et al. 2022

Crystals

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Indium tin oxide (ITO) is a functional material with great transparency, machinability, electrical conductivity and thermo–sensitivity. Based on its excellent thermoelectric performance, we designed and fabricated a multilayer transparent microfluidic chip with multiple sets of on–chip heating, local temperature measurement and positive on–chip cooling function units. Temperature control plays a significant role in microfluidic approaches, especially in the devices that are designed for bioengineering, chemical synthesis and disease detection. The transparency of the chip contributes to achieve the real–time observation of fluid flow and optical detection. The chip consists of a temperature control layer made with an etched ITO deposited glass, a PDMS (polydimethylsiloxane) fluid layer, a PDMS cooling and flow control layer. The performances of the ITO on–chip microheaters, ITO on–chip temperature sensors and two coolants were tested and analyzed in different working conditions. The positive on–chip heating and cooling were proved to be area-specific under a large temperature–regulating range. This PDMS–ITO–glass based chip could be applied to both temporal and spatial stable temperature–regulating principles for various purposes.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Thermodynamic Characterization of a Highly Transparent Microfluidic Chip with Multiple On-Chip Temperature Control Units

Yang

Wang

et al. 2022

Crystals

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Integration of microfluidic chips with biosensors

Sekhwama,

Mpofu,

Sudesh

et al. 2024

Discov Appl Sci

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The potential threat posed by disease outbreaks to diagnostic instruments demands the development of more effective biosensor technologies to counteract the risks. Diseases like SARS-CoV-2, Ebola, malaria, cholera, and many more have demonstrated beyond the limits of health care that new advancements are required for early detection and diagnosis. The rising number of diseases outbreaks has led to an increasing demand for biosensors that are more effective and quicker to utilize in healthcare settings. A biosensor incorporated with microfluidic chips offers an improved detection compared to traditional or classical biosensors. Microfluidic chips improve the performance of the biosensors by allowing automation, mixing, separation, throughput processing, and transport of the analytes to desired reactors. A biosensor incorporated with a microfluidic chip has improved sensitivity, easy operation and can use small volumes of samples to process the results. The effectiveness of biosensors depends also on the materials used in its fabrication and there are many materials used for fabrication which are reviewed in this work. This paper reviews the potential advantages of the use of microfluidic chips to enhance the performance of biosensors, materials used to fabricate the chips, and potential electrodes incorporated into microfluidic chips which improve the detection time by shortening the processing time for biosensors at the point of care service. This work also reviews new technologies which are not previously addressed other reviews including, integration of cell-imprinted polymers with microfluidic sensors and delved into future technologies outlook.

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Integration of Ultra-Low Volume Pneumatic Microfluidics with a Three-Dimensional Electrode Network for On-Chip Biochemical Sensing

Cited by 2 publications

References 36 publications

Thermodynamic Characterization of a Highly Transparent Microfluidic Chip with Multiple On-Chip Temperature Control Units

Thermodynamic Characterization of a Highly Transparent Microfluidic Chip with Multiple On-Chip Temperature Control Units

Integration of microfluidic chips with biosensors

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