ItemAvailable
PLInk — PEGDA-Based Photopolymer Ink for LCD 3D Printing
Faculty of Medicine and Health Sciences
Biomedical Engineering
McGill University
Notes:
- Poly(ethylene glycol) diacrylate-based “PLInk” optimized for low-cost LCD 3D printing (pixel pitch 18–35 µm) with high resolution and rapid cure times.
- Achieves lateral features down to 75 µm, embedded membranes 22 µm thick, and circular channel radii of 110 µm.
- Demonstrated printing of functional microfluidic modules—3D micromixers, membrane microvalves, and autonomous capillaric circuits (IFN-γ detection LOD 12 pg mL⁻¹, CV 6.8%)—and high-throughput organ-on-a-chip devices in 384-well plate format (3,420 devices/8 h).
- Biocompatible formulation; opens up democratized access to ready-to-use microfluidic and organ-on-a-chip fabrication anywhere.
Juncker Lab
Faculty of Medicine and Health Sciences
Research lab focused on advancing scientific knowledge and innovation.
DJ
David Juncker
ItemAvailable
PLInk — PEGDA-Based Photopolymer Ink for LCD 3D Printing
Faculty of Medicine and Health Sciences
Biomedical Engineering
McGill University
Notes:
- Poly(ethylene glycol) diacrylate-based “PLInk” optimized for low-cost LCD 3D printing (pixel pitch 18–35 µm) with high resolution and rapid cure times.
- Achieves lateral features down to 75 µm, embedded membranes 22 µm thick, and circular channel radii of 110 µm.
- Demonstrated printing of functional microfluidic modules—3D micromixers, membrane microvalves, and autonomous capillaric circuits (IFN-γ detection LOD 12 pg mL⁻¹, CV 6.8%)—and high-throughput organ-on-a-chip devices in 384-well plate format (3,420 devices/8 h).
- Biocompatible formulation; opens up democratized access to ready-to-use microfluidic and organ-on-a-chip fabrication anywhere.
Juncker Lab
Faculty of Medicine and Health Sciences
Research lab focused on advancing scientific knowledge and innovation.
DJ
David Juncker
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