High-resolution low-cost LCD 3D printing for microfluidics and organ-on-a-chip devices

The fabrication of microfluidic devices has progressed from cleanroom manufacturing to replica molding in polymers, and more recently to direct manufacturing by subtractive ( e.g. , laser machining) and additive ( e.g. , 3D printing) techniques, notably digital light processing (DLP) photopolymeriza...

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Bibliographic Details
Published in:Lab on a chip 2024-05, Vol.24 (1), p.2774-279
Main Authors: Shafique, Houda, Karamzadeh, Vahid, Kim, Geunyong, Shen, Molly L, Morocz, Yonatan, Sohrabi-Kashani, Ahmad, Juncker, David
Format: Article
Language:English
Subjects:
3-D printers
Biocompatibility
Cleanrooms
Devices
High resolution
Inhomogeneity
Inks
Laser machining
LCDs
Liquid crystal displays
Low cost
Manufacturing
Membranes
Microfluidic devices
Microfluidics
Photopolymerization
Pixels
Polyethylene glycol
Three dimensional printing
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Summary:The fabrication of microfluidic devices has progressed from cleanroom manufacturing to replica molding in polymers, and more recently to direct manufacturing by subtractive ( e.g. , laser machining) and additive ( e.g. , 3D printing) techniques, notably digital light processing (DLP) photopolymerization. However, many methods require technical expertise and DLP 3D printers remain expensive at a cost ∼15-30 K USD with ∼8 M pixels that are 25-40 μm in size. Here, we introduce (i) the use of low-cost (∼150-600 USD) liquid crystal display (LCD) photopolymerization 3D printing with ∼8-58 M pixels that are 18-35 μm in size for direct microfluidic device fabrication, and (ii) a poly(ethylene glycol) diacrylate-based ink developed for LCD 3D printing (PLInk). We optimized PLInk for high resolution, fast 3D printing and biocompatibility while considering the illumination inhomogeneity and low power density of LCD 3D printers. We made lateral features as small as 75 μm, 22 μm-thick embedded membranes, and circular channels with a 110 μm radius. We 3D printed microfluidic devices previously manufactured by other methods, including an embedded 3D micromixer, a membrane microvalve, and an autonomous capillaric circuit (CC) deployed for interferon-γ detection with excellent performance (limit of detection: 12 pg mL −1 , CV: 6.8%). We made PLInk-based organ-on-a-chip devices in 384-well plate format and produced 3420 individual devices within an 8 h print run. We used the devices to co-culture two spheroids separated by a vascular barrier over 5 days and observed endothelial sprouting, cellular reorganization, and migration. LCD 3D printing together with tailored inks pave the way for democratizing access to high-resolution manufacturing of ready-to-use microfluidic and organ-on-a-chip devices by anyone, anywhere. Microfluidic and organ-on-a-chip device fabrication via low-cost LCD photopolymerization 3D printing using a custom photoink for high-resolution, fast, and throughput direct manufacturing.
ISSN:1473-0197
1473-0189
1473-0189
DOI:10.1039/d3lc01125a