Versatile and Low-Cost Fabrication of Modular Lock-and-Key Microfluidics for Integrated Connector Mixer Using a Stereolithography 3D Printing

Anshori, Isa; Lukito, Vincent; Adhawiyah, Rafita Erli; Putri, Delpita; Harimurti, Suksmandhira; Rajab, Tati Latifah Erawati; Pradana, Arfat; Akbar, Mohammad Rizki; Syamsunarno, Mas Rizky Anggun Adipurna; Handayani, Murni; Purwidyantri, Agnes; Prabowo, Briliant Adhi

doi:10.3390/mi13081197

Cited by 5 publications

(7 citation statements)

References 46 publications

(55 reference statements)

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“…Another advantage of passive components is their smaller footprint, making them suitable for micro-scale devices. These components also have a simple control operation, which can help reduce complexity in microfluidic systems [20,21]. TVs have been studied for their use as passive components in microfluidics because of their straightforward design and effective fluidic control.…”

Section: Of 23mentioning

confidence: 99%

Tesla Valve Microfluidics: The Rise of Forgotten Technology

Purwidyantri¹,

Prabowo²

2023

Preprint

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The Tesla valve (TV), a valvular conduit invented by Nicola Tesla over a decade ago, has recently gained significant attention and application in various fields due to the growing interest in microfluidics and nanofluidics. The unique architecture of TV characterized by an asymmetrical design and an arc-shaped channel, has long been an intriguing yet underrated design for building a passive component in a microfluidic system. While previously regarded as a technology without significant use, TV structures have been implemented in wearable devices, thermal manipulation fluidics, micromixers, micropumps, and fuel cell devices. This article presents the first comprehensive review of TV structures in the literature, which has seen significant growth in the last two years. The review discusses typical TV structures, including single-stage TV (STV), multistage TV (MSTV), and TV derivatives (TVD), along with their characteristics and potential applications. The designs of these structures vary based on their intended applications, but all are constructed based on the fundamental principle of the TV structure. Finally, future trends and potential applications of TV structures are summarized and discussed. This review provides a valuable reference for students, early-career scientists, and practitioners in the field of fluidic devices, particularly those interested in using TV structures as passive components.

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Section: Of 23mentioning

confidence: 99%

Tesla Valve Microfluidics: The Rise of Forgotten Technology

Purwidyantri¹,

Prabowo²

2023

Preprint

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“…Meanwhile, for the SFC type, the cylindrical inlet-outlet on the above surface of the platform has a diameter of 0.718 mm, designed to t the diameter of the syringe needle. The fabrication method and inspection were described in detail in (Anshori et al 2022). The channel dimension analysis of the platforms was carried out visually by observation and measurement using an optical microscope and ImageJ application.…”

Section: Flow Cell Designsmentioning

confidence: 99%

“…The concentration of the potassium ferricyanide solution is varied into six values: 1, 2. Both platform designs were printed using a 3D printer with the following printing parameters: layer thickness of 0.05 mm, normal exposure time of 3 s, bottom exposure time of 35 s, bottom layers of 4, and off time of 1 s. The printing process took 29 minutes for the bottom part of both types, 29 minutes for the upper part of the TFC type, and 57 minutes for the upper part of the SFC type, with a horizontal printing orientation (Anshori et al 2022). Speci cally for the upper part of the SFC type, since there is a hole on each side of the platform (top and bottom), 75% of support was used on one side during the printing process to prevent the platform from collapsing during the printing process.…”

Section: Electrochemical Analysismentioning

confidence: 99%

“…However, this technique requires a long process, complicated method, high cost, and often results in leakage on the platform due to a not evenly distributed pressure given during the fabrication process (Chen et al 2016). To overcome these problems, many studies relied on micro-milling and 3D printing methods (Anshori et al 2022;Prabowo et al 2022). This method offers a more accessible, simpler, and relatively shorter fabrication time (Gale et al 2018).…”

Section: Introductionmentioning

confidence: 99%

“…This method offers a more accessible, simpler, and relatively shorter fabrication time (Gale et al 2018). There are several variations of 3D printing methods, such as Fused Deposition Modelling (FDM), Robocasting, Multi-Jet Modelling (MJM), and Stereolithography (SLA) (Sharafeldin et al 2018;Anshori et al 2022). SLA method prints the platform layer by layer using a resin polymerized by UV light at a wavelength of about 405 nm.…”

Section: Introductionmentioning

confidence: 99%

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Development of 3D printed click-and-fit modular microfluidics for an integrated electrochemical platform

Anshori

Munifah

Ariasena

et al. 2022

Preprint

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In this article, we presented the development of fully modular microfluidic flow cells for an electrochemical using 3D printing. The proposed devices are potential for electrochemical measurements using a small sample volume on a fully portable, reusable, simply fabricated, low-cost, PDMS-free, and leakage-free flow cell. This concept offers a simple, controllable sample over the conventional electrochemical platform with a three-electrode system, which requires a considerable volume of samples or a non-controllable drop cast method for sequential protocols. We demonstrated an easy alignment and lock, namely, click-and-fit modular microfluidics, for quick and easy assembly and disassembly of flow cell modules using magnetic force instead of the screw, polymer glue, or resin. Two microfluidic modules were presented using tube- and syringe-flow cells (TFC and SFC) to integrate the screen-printed carbon electrodes (SPCE) in the electrochemical sensor. The proof-of-concept of the integrated sensor-microfluidic platforms was conducted under cyclic voltammetry using a tiny volume of a ferricyanide redox probe at only ~50 µL, differential pulse voltammetry, and square wave voltammetry. Implementing the proposed click-and-fit microfluidic modules in electrochemical detection achieves higher current peaks than droplet measurements. These flow cell modules are promising for biosensing applications using a small volume of physiological fluid samples.

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