Fixed-volume metering microdispenser module

Puntambekar, Aniruddha; Choi, Jin‐Woo; Ahn, Chong H.; Kim, Sura; Makhijani, Vinod B.

doi:10.1039/b206934b

Cited by 26 publications

(14 citation statements)

References 15 publications

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“…We have previously reported the development of a smart, passive microfluidic control technique, which relies on the geometrical dimensions and surface properties of the microfluidic channels to control microfluidic sequencing. 17,18 It is highly required for microfluidic sealing to prevent blood sample backflow when delivering blood sample to the sensing chamber by applying pressure.…”

Section: Methodsmentioning

confidence: 99%

Development of functional lab-on-a-chip on polymer for point-of-care testing of metabolic parameters

Lee

Han

et al. 2008

Lab Chip

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This paper presents the development of an easy-to-handle and disposable clinical diagnostic lab-on-a-chip using fully integrated plastic microfluidic components, which has the sampling/identifying capability to make fast and reliable measurements of metabolic parameters from human whole blood. A smart and functional lab-on-a-chip cartridge, which incorporates a full on-chip auto-calibration function for in the field applications, has been developed, and then fully characterized using a portable analyzer (3 (1/4)''x 5''x 1'') with multi-analyte detection capability. In addition, several new approaches in realizing smart and functional lab-on-a-chips on polymer have been adopted, which include the pinch valve for automatic fluidic sealing, a by-pass channel as the sampling indicator, and a robust connector design for long analyzer lifetimes. Metabolic parameters such as glucose, lactate, and partial oxygen from human whole blood have been successfully measured using the functional polymer lab-on-a-chips and the portable analyzer developed in this work.

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Section: Methodsmentioning

confidence: 99%

Development of functional lab-on-a-chip on polymer for point-of-care testing of metabolic parameters

Lee

Han

et al. 2008

Lab Chip

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“…Because propulsion is not automatic in hydrophobic channels, prepressurized air pockets were employed that were actuated by heat-induced membrane puncture. 24…”

Section: Capillary Flow In Loc Systems Other Than For Pocmentioning

confidence: 99%

Young 4ever—the use of capillarity for passive flow handling in lab on a chip devices

2006

Lab Chip

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“…Mercury is injected into the mercury reservoir (y150 nL) through inlet-1, and the passive microvalve1 stops the flow of mercury because it functions as a capillary pressure barrier. 22 After mercury injection, UV-curing epoxy is injected through inlet-2 and outlet-2 to seal one end of reservoir. The heater under the reservoir heats the air bubble in air reservoir (y6 nL) to actuate the mercury.…”

Section: Experimental 1 Device Principle and Structurementioning

confidence: 99%

On-chip generated mercury microelectrode for heavy metal ion detection

et al. 2005

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In this paper, the on-chip generated mercury microelectrode for heavy metal ion detection has been presented. A mercury droplet (approximately 150 microm in diameter) is on-chip generated to form a microelectrode through the mercury microfluidics control. The mercury microelectrode is used to electrochemically detect the heavy metal ions. The sample solutions with different concentration of heavy metal ions (Pb(2+) and Cd(2+)) have been successfully detected on the mercury droplet microelectrode using the square wave stripping voltammetry.

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Fixed-volume metering microdispenser module

Cited by 26 publications

References 15 publications

Development of functional lab-on-a-chip on polymer for point-of-care testing of metabolic parameters

Development of functional lab-on-a-chip on polymer for point-of-care testing of metabolic parameters

Young 4ever—the use of capillarity for passive flow handling in lab on a chip devices

On-chip generated mercury microelectrode for heavy metal ion detection

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