Low-Cost Light-Based GelMA 3D Bioprinting via Retrofitting: Manufacturability Test and Cell Culture Assessment.
Juan Enrique Pérez-CortezVíctor Hugo Sánchez-RodríguezSalvador Gallegos-MartínezCristina Chuck-HernándezCiro A RodríguezMario Moises ÁlvarezGrissel Trujillo-de SantiagoElisa V VázquezJ Israel Martínez LópezPublished in: Micromachines (2022)
Light-based bioprinter manufacturing technology is still prohibitively expensive for organizations that rely on accessing three-dimensional biological constructs for research and tissue engineering endeavors. Currently, most of the bioprinting systems are based on commercial-grade-based systems or modified DIY (do it yourself) extrusion apparatuses. However, to date, few examples of the adoption of low-cost equipment have been found for light-based bioprinters. The requirement of large volumes of bioinks, their associated cost, and the lack of information regarding the parameter selection have undermined the adoption of this technology. This paper showcases the retrofitting and assessing of a low-cost Light-Based 3D printing system for tissue engineering. To evaluate the potential of a proposed design, a manufacturability test for different features, machine parameters, and Gelatin Methacryloyl (GelMA) concentrations for 7.5% and 10% was performed. Furthermore, a case study of a previously seeded hydrogel with C2C12 cells was successfully implemented as a proof of concept. On the manufacturability test, deviational errors were found between 0.7% to 13.3% for layer exposure times of 15 and 20 s. Live/Dead and Actin-Dapi fluorescence assays after 5 days of culture showed promising results in the cell viability, elongation, and alignment of 3D bioprinted structures. The retrofitting of low-cost equipment has the potential to enable researchers to create high-resolution structures and three-dimensional in vitro models.
Keyphrases
- low cost
- tissue engineering
- high resolution
- induced apoptosis
- electronic health record
- emergency department
- cell cycle arrest
- healthcare
- single molecule
- oxidative stress
- patient safety
- hyaluronic acid
- cell death
- endoplasmic reticulum stress
- quantum dots
- climate change
- high throughput
- human health
- cell wall
- bone regeneration