Capillary driven low-cost V-groove microfluidic device with high sample transport efficiency

Tian, Junfei; Kannangara, Dushmantha Sisiranath; Li, Xu; Shen, Wei

doi:10.1039/c003728a

Cited by 56 publications

(32 citation statements)

References 16 publications

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“…Bioassays made of disposable materials can be used for regular tests to detect blood typing, cancers, generic conditions, and epidemic diseases such as hepatitis and influenza [4,5,[7][8][9][10]. They can also be used to identify and filter heavy metals, chemical compounds and microbial activities in water.…”

Section: Introductionmentioning

confidence: 99%

Qualitative and quantitative detection of T7 bacteriophages using paper based sandwich ELISA

Khan

Pande

Ven

2015

Colloids and Surfaces B: Biointerfaces

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Section: Introductionmentioning

confidence: 99%

Qualitative and quantitative detection of T7 bacteriophages using paper based sandwich ELISA

Khan

Pande

Ven

2015

Colloids and Surfaces B: Biointerfaces

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“…4 below. Based on the work by Roberts et al, Khan et al [33] and Tian et al [34] have experimentally modelled liquid-penetration behaviour in V-grooves, simulating liquid movement in inter-fibre open capillaries similar to those illustrated in Fig. 4d.…”

Section: Mechanisms Of Separationmentioning

confidence: 96%

Red blood cell transport mechanisms in polyester thread-based blood typing devices

et al. 2015

Self Cite

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A recently developed blood typing diagnostic based on a polyester thread substrate has shown great promise for use in medical emergencies and in impoverished regions. The device is easy to use and transport, while also being inexpensive, accurate, and rapid. This study used a fluorescent confocal microscope to delve deeper into how red blood cells were behaving within the polyester thread-based diagnostic at the cellular level, and how plasma separation could be made to visibly occur on the thread, making it possible to identify blood type in a single step. Red blood cells were stained and the plasma phase dyed with fluorescent compounds to enable them to be visualised under the confocal microscope at high magnification. The mechanisms uncovered were in surprising contrast with those found for a similar, paper-based method. Red blood cell aggregates did not flow over each other within the thread substrate as expected, but suffered from a restriction to their flow which resulted in the chromatographic separation of the RBCs from the liquid phase of the blood. It is hoped that these results will lead to the optimisation of the method to enable more accurate and sensitive detection, increasing the range of blood systems that can be detected.

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“…In 2010, Martinez et al positioned a digital valve that introduced designed gaps to separate the paper's layers, thus strategically connecting and disconnecting the flow [80]. Other groups reported approaches for controlling fluid transport by changing the geometry of the channels and altering the width, length, and thickness of the junctions in paper-based microfluidic designs [81][82][83]. Applications of the fluidic barriers made from soluble materials for carrier flow were also presented in the literature.…”

Section: Physical Characteristics Of the Paper And/or Fiber Materialsmentioning

confidence: 99%

Paper and Fiber-Based Bio-Diagnostic Platforms: Current Challenges and Future Needs

2017

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Abstract:In this perspective article, some of the latest paper and fiber-based bio-analytical platforms are summarized, along with their fabrication strategies, the processing behind the product development, and the embedded systems in which paper or fiber materials were integrated. The article also reviews bio-recognition applications of paper/fiber-based devices, the detected analytes of interest, applied detection techniques, the related evaluation parameters, the type and duration of the assays, as well as the advantages and disadvantages of each technique. Moreover, some of the existing challenges of utilizing paper and/or fiber materials are discussed. These include control over the physical characteristics (porosity, permeability, wettability) and the chemical properties (surface functionality) of paper/fiber materials are discussed. Other aspects of the review focus on shelf life, the multi-functionality of the platforms, readout strategies, and other challenges that have to be addressed in order to obtain reliable detection outcomes.

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Capillary driven low-cost V-groove microfluidic device with high sample transport efficiency

Cited by 56 publications

References 16 publications

Qualitative and quantitative detection of T7 bacteriophages using paper based sandwich ELISA

Qualitative and quantitative detection of T7 bacteriophages using paper based sandwich ELISA

Red blood cell transport mechanisms in polyester thread-based blood typing devices

Paper and Fiber-Based Bio-Diagnostic Platforms: Current Challenges and Future Needs

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