Influence of Geometry and Surrounding Conditions on Fluid Flow in Paper-Based Devices

Walji, Noosheen; MacDonald, Brendan D.

doi:10.3390/mi7050073

Cited by 52 publications

(46 citation statements)

References 42 publications

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“…Although many POC diagnostic devices have been fabricated and tested, a transition from academia to industry is mandatory for their commercialization. Generally, these μPADs have the following limitations: (i) sample retention and evaporation issues can cause serious problems with the transportation of sample [119], (ii) variation in the specificity and sensitivity of μPADs is the main concern of the present era because it plays a crucial role in avoiding false-positive results [120], and (iii) reagents used in these μPADs, such as enzymes, antigens, and antibodies, must withstand the harsh environmental conditions met during shipping and storage processes [3,121]. …”

Section: Future Of Paper-based Microfluidic Devicesmentioning

confidence: 99%

Paper-based analytical devices for clinical diagnosis: recent advances in the fabrication techniques and sensing mechanisms

Sher

Zhuang²,

Demirci³

et al. 2017

Expert Review of Molecular Diagnostics

211

157

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Introduction There is a significant interest in developing inexpensive portable biosensing platforms for various applications including disease diagnostics, environmental monitoring, food safety, and water testing at the point-of-care (POC) settings. Current diagnostic assays available in the developed world require sophisticated laboratory infrastructure and expensive reagents. Hence, they are not suitable for resource-constrained settings with limited financial resources, basic health infrastructure, and few trained technicians. Cellulose and flexible transparency paper-based analytical devices have demonstrated enormous potential for developing robust, inexpensive and portable devices for disease diagnostics. These devices offer promising solutions to disease management in resource-constrained settings where the vast majority of the population cannot afford expensive and highly sophisticated treatment options. Areas covered In this review, the authors describe currently developed cellulose and flexible transparency paper-based microfluidic devices, device fabrication techniques, and sensing technologies that are integrated with these devices. The authors also discuss the limitations and challenges associated with these devices and their potential in clinical settings. Expert commentary In recent years, cellulose and flexible transparency paper-based microfluidic devices have demonstrated the potential to become future healthcare options despite a few limitations such as low sensitivity and reproducibility.

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Section: Future Of Paper-based Microfluidic Devicesmentioning

confidence: 99%

Paper-based analytical devices for clinical diagnosis: recent advances in the fabrication techniques and sensing mechanisms

Sher

Zhuang²,

Demirci³

et al. 2017

Expert Review of Molecular Diagnostics

211

157

View full text Add to dashboard Cite

show abstract

“…Past work has demonstrated that the liquid front observed while liquid is flowing through paper does not indicate that all of the paper behind this front is completely saturated with the liquid (Bico & Quéré 2003). This was also confirmed in a recent study by Walji & MacDonald (2016) where they observed post-wetting flow into paper after the visual liquid front reached the end of the strip. This effect is often attributed to the slower filling of smaller inter-fibre pores as a result of the distribution of pore sizes in a complex fibre matrix like paper.…”

Section: Overviewmentioning

confidence: 63%

Flow of liquids through paper

MacDonald

2018

J. Fluid Mech.

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5 μm 5 μm Cross section of paper Single fibreThe flow of liquids through paper is challenging to model due to the complexity and disordered layout of the fibre matrix. The expanding use and capability of microfluidic paper-based analytical devices (µPADs) and their requirement for precision has increased the need to accurately predict the flow of liquids through paper. Many studies have developed models and revealed some of the physical mechanisms responsible for the flow behaviour, but we still lack a complete understanding, particularly in relation to how the fluid fills the various voids with a wide range of shapes and sizes in the fibre matrix of paper. In the featured article, Chang et al. (J. Fluid Mech., vol. 845, 2018, 36-50) used a combined experimental and theoretical approach to uncover the importance of the liquid filling the intra-fibre pores, showed that this results in deviation from the flow behaviour predicted by the Lucas-Washburn equation and developed a model which accounts for this effect.

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“…[10a] Paper is an excellent substrate for automatic multistep processes, since it integrates a passive fluid pumping through the capillary forces of cellulose fibers; however, this property is dependent on not only paper type [116] but also many other parameters. It is dependent on the geometry of the microfluidic channel, [116][117] the presence of wax boundaries, [118] the ambient conditions (such as temperature and moisture), [116,119] the confinement of the space, [33b,120] etc. These articles give insights into the physical mechanisms involved in the passive pumping of paper, making the subject possible to be studied by anyone, since it is observed by the naked eye.…”

Section: Advanced Characterization Of Paper Devicesmentioning

confidence: 99%

Emerging Considerations for the Future Development of Electrochemical Paper‐Based Analytical Devices

et al. 2018

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Meeting the current needs for easier, more precise and faster analyses that also follow the principles of green analytical chemistry requires novel analytical chemistry strategies. Since the appearance in this century of the first device based on a paper platform, many studies have been presented in the literature, providing a wide range of designs and possibilities for the application of paper platforms to electroanalytical systems. This Review gives an overview of the field and can pave the way for the future development of electrochemical paper‐based analytical devices. We also present a critical point of view regarding what has been investigated and developed and what is still missing. This Review discusses the efforts made in the field related to important topics such as the choice of the paper substrate, the device construction process, the characterization of the device, and applications in different areas. In this way, we indicate some steps necessary for optimizing the design of the devices, with a focus on multidisciplinary collaborations that could move entire systems from the bench of the laboratory to the field.

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Influence of Geometry and Surrounding Conditions on Fluid Flow in Paper-Based Devices

Cited by 52 publications

References 42 publications

Paper-based analytical devices for clinical diagnosis: recent advances in the fabrication techniques and sensing mechanisms

Paper-based analytical devices for clinical diagnosis: recent advances in the fabrication techniques and sensing mechanisms

Flow of liquids through paper

Emerging Considerations for the Future Development of Electrochemical Paper‐Based Analytical Devices

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