Passive micropumping in microfluidics for point-of-care testing

Xu, Linfeng; Wang, Anyang; Li, Xiangpeng; Oh, Kwang W.

doi:10.1063/5.0002169

Cited by 47 publications

(34 citation statements)

References 160 publications

(190 reference statements)

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“…The methods based on POCT can be divided into self-driving testing and external force-driving testing according to driving force [31]. Self-driving detection includes the use of capillary effect, negative pressure, or chemical reaction to generate gas [32,130], etc. to promote the reaction and output related signals, the external force-driving detection usually uses hand push, finger trigger button etc.…”

Section: Detection Methods Based On Point-of-care Testing (Poct)mentioning

confidence: 99%

Electrochemical Detection and Point-of-Care Testing for Circulating Tumor Cells: Current Techniques and Future Potentials

Han

Sun

et al. 2020

Sensors

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Circulating tumor cells (CTCs) are tumor cells that escaped from the primary tumor or the metastasis into the blood and they play a major role in the initiation of metastasis and tumor recurrence. Thus, it is widely accepted that CTC is the main target of liquid biopsy. In the past few decades, the separation of CTC based on the electrochemical method has attracted widespread attention due to its convenience, rapidness, low cost, high sensitivity, and no need for complex instruments and equipment. At present, CTC detection is not widely used in the clinic due to various reasons. Point-of-care CTC detection provides us with a possibility, which is sensitive, fast, cheap, and easy to operate. More importantly, the testing instrument is small and portable, and the testing does not require specialized laboratories and specialized clinical examiners. In this review, we summarized the latest developments in the electrochemical-based CTC detection and point-of-care CTC detection, and discussed the challenges and possible trends.

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Section: Detection Methods Based On Point-of-care Testing (Poct)mentioning

confidence: 99%

Electrochemical Detection and Point-of-Care Testing for Circulating Tumor Cells: Current Techniques and Future Potentials

Han

Sun

et al. 2020

Sensors

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“…Several device modifications have been attempted to overcome this challenge, such as by varying the dimensions of microchannels to control fluid movement [ 12 ] and the incorporation of porous materials at the outlets to absorb the fluid and increase micropumping time [ 27 ]. Furthermore, liquid evaporation may also occur after capillary fill and depends on the microchannel dimensions and temperature of the devices [ 84 ].…”

Section: Conclusion and Future Challengesmentioning

confidence: 99%

Capillary-Driven Flow Microfluidics Combined with Smartphone Detection: An Emerging Tool for Point-of-Care Diagnostics

et al. 2020

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Point-of-care (POC) or near-patient testing allows clinicians to accurately achieve real-time diagnostic results performed at or near to the patient site. The outlook of POC devices is to provide quicker analyses that can lead to well-informed clinical decisions and hence improve the health of patients at the point-of-need. Microfluidics plays an important role in the development of POC devices. However, requirements of handling expertise, pumping systems and complex fluidic controls make the technology unaffordable to the current healthcare systems in the world. In recent years, capillary-driven flow microfluidics has emerged as an attractive microfluidic-based technology to overcome these limitations by offering robust, cost-effective and simple-to-operate devices. The internal wall of the microchannels can be pre-coated with reagents, and by merely dipping the device into the patient sample, the sample can be loaded into the microchannel driven by capillary forces and can be detected via handheld or smartphone-based detectors. The capabilities of capillary-driven flow devices have not been fully exploited in developing POC diagnostics, especially for antimicrobial resistance studies in clinical settings. The purpose of this review is to open up this field of microfluidics to the ever-expanding microfluidic-based scientific community.

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“…Passively driven MF avoids bulky external supporting equipment and only employs basic laboratory instruments such as micropipettes by utilizing surface tension, pressure-driven gravity, osmosis, vacuum suction and capillary force as the movement forces [27][28][29][30] . Such an emerging strategy for the movement of nucleic acid samples is achieved with characteristics including easy fabrication, a lack of external power, low cost, compactness and portability.…”

Section: Introductionmentioning

confidence: 99%

Passively Driven Microfluidic Device with Simple Operation for Quantitative Droplet LAMP Sssay for Point-of-Care Analysis

Lin

2021

Preprint

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Since polymerase chain reaction (PCR) has become a vital tool for disease diagnosis, the development of precise applied PCR technologies in point-of care testing (POCT) has become more significant. The microfluidic-based PCR platform offers a great opportunity for on-site diagnosis efficiency, and the system is aimed at user-friendly access. Herein, we demonstrate a microfluidic system with simple operation that provides reliable nucleic acid results from 18 uniform droplets via LAMP qPCR detection. By using only micropipette regulation, users are able to control the nanoliter scale of the droplets in this valve-free and pump-free microfluidic (MF) chip. Based on the oil enclosure method and impermeable fabrication, we successfully preserved the reagent inside the microfluidic system, which significantly reduced the fluid loss and condensation. The relative standard deviation (RSD) of the fluorescence intensity between the droplets and during the heating process was <5% and 2.0%, respectively. Additionally, for different nucleic acid detection methods, the MF-LAMP chip in this study showed good applicability to both genome detection and gene expression analysis.

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Passive micropumping in microfluidics for point-of-care testing

Cited by 47 publications

References 160 publications

Electrochemical Detection and Point-of-Care Testing for Circulating Tumor Cells: Current Techniques and Future Potentials

Electrochemical Detection and Point-of-Care Testing for Circulating Tumor Cells: Current Techniques and Future Potentials

Capillary-Driven Flow Microfluidics Combined with Smartphone Detection: An Emerging Tool for Point-of-Care Diagnostics

Passively Driven Microfluidic Device with Simple Operation for Quantitative Droplet LAMP Sssay for Point-of-Care Analysis

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