A vortex-type micromixer utilizing pneumatically driven membranes

Yang, Sung-Yi; Lin, Jingjun; Lee, Gwo‐Bin

doi:10.1088/0960-1317/19/3/035020

Cited by 69 publications

(50 citation statements)

References 40 publications

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“…[10][11][12] A variety of microfluidic devices have been fabricated based on this microfabrication process, such as micropumps, 13 microvalves, 14 microseparators, 15 microconcentrators, 16 and micromixers. 17 Furthermore, these PDMS-based microfluidic devices can even be integrated to perform a specific assay for various applications such as molecular diagnosis, 18 protein analysis, 19 and cell studies. 20 However, there are still potential limitations for PDMS-based microfluidic systems.…”

Section: A Microfluidicsmentioning

confidence: 99%

Stem cells in microfluidics

Lin²,

Lee³

2011

Biomicrofluidics

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Microfluidic techniques have been recently developed for cell-based assays. In microfluidic systems, the objective is for these microenvironments to mimic in vivo surroundings. With advantageous characteristics such as optical transparency and the capability for automating protocols, different types of cells can be cultured, screened, and monitored in real time to systematically investigate their morphology and functions under well-controlled microenvironments in response to various stimuli. Recently, the study of stem cells using microfluidic platforms has attracted considerable interest. Even though stem cells have been studied extensively using bench-top systems, an understanding of their behavior in in vivo-like microenvironments which stimulate cell proliferation and differentiation is still lacking. In this paper, recent cell studies using microfluidic systems are first introduced. The various miniature systems for cell culture, sorting and isolation, and stimulation are then systematically reviewed. The main focus of this review is on papers published in recent years studying stem cells by using microfluidic technology. This review aims to provide experts in microfluidics an overview of various microfluidic systems for stem cell research.

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Section: A Microfluidicsmentioning

confidence: 99%

Stem cells in microfluidics

Lin²,

Lee³

2011

Biomicrofluidics

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“…Furthermore, an efficient mixing effect was also be generated by utilizing the central mixing unit with a similar mechanism (Yang et al 2009). For instance, two different fluidic samples were drawn simultaneously into the fluidic reservoir of the central mixing unit when the air in the air chamber of the two microvalves and the central mixing unit was evacuated with the aid of the vacuum pump.…”

Section: Working Principle Of the Diagnostic Assaymentioning

confidence: 99%

Integrated microfluidic system for the identification and multiple subtyping of influenza viruses by using a molecular diagnostic approach

Wang

Lien

Hung

et al. 2012

Microfluid Nanofluid

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This study presents an integrated microfluidic system capable of rapid diagnosis of influenza infection and subtyping of influenza viruses. The viral RNA extraction module and reverse-transcription polymerase chain reaction module were integrated with an external optical detection module into the microsystem. Magnetic beads conjugated with specific nucleotide probes were first used to capture target RNA from influenza viral particles after thermolysis/hybridization processes. The hybridized target RNA was purified and collected by an external magnetic field. Finally, the extracted RNA was amplified by one-step RT-PCR products and detected by optical detection module with TaqMan fluorescence system. Moreover, the LOD was experimentally found to be 10 2 copies for influenza A H1/H3 and influenza B viruses. Experimental results also showed that different subtypes of influenza viruses were diagnosed by using multiplex RT-PCR process and automatically completed within 110 min in the developed microfluidic system.

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“…The width and the depth of the chip channels were measured to be 1 mm and 300 mm, respectively. Finally, the PDMS structures and the glass substrate are bonded together utilizing an oxygen plasma treatment to form the complete microfluidic chip [26].…”

Section: Fabrication Processmentioning

confidence: 99%

A multi‐functional electrochemical sensing system using microfluidic technology for the detection of urea and creatinine

et al. 2011

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This study presents a new microfluidic system capable of precise measurements of two important biomarkers, urea and creatinine, automatically. In clinical applications, high levels of these two biomarkers are early indicators of nephropathy or renal failure and should be monitored on a regular basis. The microfluidic system is composed of a microfluidic chip, a control circuit system, a compressed air source and several electromagnetic valves to form a handheld system. The microfluidic chip is fabricated by using micro-electromechanical systems and microfluidic techniques comprising electrochemical sensor arrays and polydimethylsiloxane-based microfluidic structures such as micropumps/micromixers, normally closed valves and microchannels. The microfluidic system performs a variety of critical processes including sample pretreatment, mixing, transportation and detection on a single chip. The experimental results show that the entire procedure takes approximately 40 min, which is much faster than the traditional method (more than 6 h). Furthermore, the total sample volume consumed in each operation is only 0.1 mL, which is significantly less than that required in a large system (5 mL). The developed automatic microfluidic system may provide a powerful platform for further clinical applications.

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A vortex-type micromixer utilizing pneumatically driven membranes

Cited by 69 publications

References 40 publications

Stem cells in microfluidics

Stem cells in microfluidics

Integrated microfluidic system for the identification and multiple subtyping of influenza viruses by using a molecular diagnostic approach

A multi‐functional electrochemical sensing system using microfluidic technology for the detection of urea and creatinine

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