Modifying Wicking Speeds in Paper-Based Microfluidic Devices by Laser-Etching

Kalish, Brent; Tan, Mick Kyle; Tsutsui, Hideaki

doi:10.3390/mi11080773

Cited by 24 publications

(7 citation statements)

References 35 publications

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“…For example, laser etching of a commercial hydrophobic coated paper (e.g., parchment paper, wax paper, palette paper), as reported by Chitnis et al, enables selective modification of the paper to allow for localization of aqueous reagents . Laser etching can also be applied to a native, hydrophilic paper to tune the wicking speed of the PAD . Laser cutting enables the fabrication of a stand-alone PAD.…”

Section: Fabrication Methodsmentioning

confidence: 99%

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Microfluidic Paper-Based Analytical Devices: From Design to Applications

et al. 2021

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Microfluidic paper-based analytical devices (μPADs) have garnered significant interest as a promising analytical platform in the past decade. Compared with traditional microfluidics, μPADs present unique advantages, such as easy fabrication using established patterning methods, economical cost, ability to drive and manipulate flow without equipment, and capability of storing reagents for various applications. This Review aims to provide a comprehensive review of the field, highlighting fabrication methods available to date with their respective advantages and drawbacks, device designs and modifications to accommodate different assay needs, detection strategies, and the growing applications of μPADs. Finally, we discuss how the field needs to continue moving forward to realize its full potential.

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Section: Fabrication Methodsmentioning

confidence: 99%

“…37 Laser etching can also be applied to a native, hydrophilic paper to tune the wicking speed of the PAD. 38 Laser cutting enables the fabrication of a stand-alone PAD. With no hydrophobic barrier used, the PAD can be employed for applications that involve organic solvents.…”

Section: Fabrication Methodsmentioning

confidence: 99%

Microfluidic Paper-Based Analytical Devices: From Design to Applications

et al. 2021

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“…[ 1,2,5,21,27,35,32,36 ] Shaping techniques are relatively expensive due to the necessary equipment. [ 10,23,35,37–39 ] Tuning fluid transport through the fiber type, fiber density, or paper grammage bares the advantage of simple integration into existing paper fabrication processes. None of these approaches allows to tune fluid flow in all three dimensions of a paper sheet, although, this would open new possibilities such as sensitivity enhancement and the design of multifunctional microfluidic paper‐based devices or asymmetric wettability for paper‐based separation and packaging.…”

Section: Introductionmentioning

confidence: 99%

Mechanistic Understanding and Three‐Dimensional Tuning of Fluid Imbibition in Silica‐Coated Cotton Linter Paper Sheets

Mikolei

Neuenfeld

Paech

et al. 2022

Adv Materials Inter

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Intensive research has been carried out in point-of-care diagnostics (POC), in particular in the area of lateral flow assays, sensor technology, and labon-a-chip implementations. For example, different biomarkers like hormones, DNA, RNA, proteins or different metabolites, [1] including inflammatory markers such as Interleukin 8, [2,3] or cancer biomarkers in the context of an early cancer diagnosis, [4,5] as well as the concentration of glucose in blood, sweat or urine was detected. [6][7][8][9][10][11][12][13] In addition to medical diagnosis paper-based microfluidic devices are used as sensors for detection of environmental pollution, [1,14] pesticide detection, [15] determination of nitrate concentration in water, [16] or as a sensor to detect heavy metals such as copper, cobalt, nickel, lead or mercury. [17][18][19][20][21][22][23][24][25] Fluid transport control in paper, a key feature for μPAD design, is to date achieved by either hydrophobic barrier deposition, often using wax or hydrophobic polymer such as polystyrene to adjust the channel width, or secondly by shaping of the paper fiber itself, and thirdly by adjusting the paper composition. [1,[26][27][28][29] To improve fluid mixing, wax pillars printed into the channel have been demonstrated to slow down the fluid flow and to create turbulences whereby a better mixing and distribution is achieved. [30,31] In a preliminary work of our research group redox gating of fluid imbibition in silica-coated paper sheets has been demonstrated using redox-responsive polymers. These stimuli-responsive polymers allow to switch from fluid exclusion to fluid imbibition. [32] Further examples demonstrating switching from fluid exclusion to fluid imbibition use PNIPAAm as temperature-responsive coating. [33,34] These approaches differ in their applicability: Hydrophobizing agents such as wax, polystyrene or PDMS are deposited on the papers using various printing-, stamping, dipping-or spraying processes or even grafting polymerization.

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“…CO 2 laser-based fabrication of microfluidic substrates has, for example, been performed with common materials such as glass and poly methylmethacrylate (PMMA) sheets and the influence of the laser settings and the length and strength of surface treatments on the production of optimal microchannel profiles and on surface smoothness was demonstrated [ 32 , 33 ]. Applications of laser-fabricated microfluidic devices include droplet digital polymerase chain reaction (PCR) [ 34 ], droplet generation [ 35 ], wicking speed modulation on paper microfluidic devices [ 36 ] and culturing of embryonic bodies [ 37 ]. Feasibility trials have also been conducted with standalone devices for CNC milling [ 5 ] and 3D FDM printing [ 38 , 39 , 40 , 41 ], with satisfactory results.…”

Section: Introductionmentioning

confidence: 99%

A Low-Cost 3-in-1 3D Printer as a Tool for the Fabrication of Flow-Through Channels of Microfluidic Systems

Thaweskulchai

Schulte

2021

Micromachines

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Recently published studies have shown that microfluidic devices fabricated by in-house three-dimensional (3D) printing, computer numerical control (CNC) milling and laser engraving have a good quality of performance. The 3-in-1 3D printers, desktop machines that integrate the three primary functions in a single user-friendly set-up are now available for computer-controlled adaptable surface processing, for less than USD 1000. Here, we demonstrate that 3-in-1 3D printer-based micromachining is an effective strategy for creating microfluidic devices and an easier and more economical alternative to, for instance, conventional photolithography. Our aim was to produce plastic microfluidic chips with engraved microchannel structures or micro-structured plastic molds for casting polydimethylsiloxane (PDMS) chips with microchannel imprints. The reproducability and accuracy of fabrication of microfluidic chips with straight, crossed line and Y-shaped microchannel designs were assessed and their microfluidic performance checked by liquid stream tests. All three fabrication methods of the 3-in-1 3D printer produced functional microchannel devices with adequate solution flow. Accordingly, 3-in-1 3D printers are recommended as cheap, accessible and user-friendly tools that can be operated with minimal training and little starting knowledge to successfully fabricate basic microfluidic devices that are suitable for educational work or rapid prototyping.

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Modifying Wicking Speeds in Paper-Based Microfluidic Devices by Laser-Etching

Cited by 24 publications

References 35 publications

Microfluidic Paper-Based Analytical Devices: From Design to Applications

Microfluidic Paper-Based Analytical Devices: From Design to Applications

Mechanistic Understanding and Three‐Dimensional Tuning of Fluid Imbibition in Silica‐Coated Cotton Linter Paper Sheets

A Low-Cost 3-in-1 3D Printer as a Tool for the Fabrication of Flow-Through Channels of Microfluidic Systems

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