Journal
ACS BIOMATERIALS SCIENCE & ENGINEERING
Volume 9, Issue 5, Pages 2663-2671Publisher
AMER CHEMICAL SOC
DOI: 10.1021/acsbiomaterials.3c00408
Keywords
photopolymerization; cell scaffold; microstructure; degradable polymer
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Engineered scaffolds are widely used in cellular transplantations for tissue engineering applications. Photopolymerization is a precise fabrication technique that allows for control of properties and structure. In this study, photopolymerization was used to generate degradable PCLTA scaffolds, and the impact of photopolymerization parameters on scaffold properties and cell loading capacity was examined.
Engineered scaffolds are commonly used to assist in cellular transplantations, providing crucial support and specific architecture for a variety of tissue engineering applications. Photopolymerization as a fabrication technique for cell scaffolds enables precise spatial and temporal control of properties and structure. One simple technique to achieve a two-dimensional structure is the use of a patterned photomask, which results in regionally selective photo-cross-linking. However, the relationships between photopolymerization parameters like light intensity and exposure time and outcomes like structural fidelity and mechanical properties are not well-established. In this work, we used photopolymerization to generate degradable polycaprolactone triacrylate (PCLTA) scaffolds with a defined microstructure. We examined the impact of light intensity and exposure time on scaffold properties such as shear modulus and micropore structure. To assess feasibility in a specific application and determine the relationship between parameter-driven properties and cell loading, we cultured retinal progenitor cells on the PCLTA scaffolds. We found that light intensity and polymerization time directly impact the scaffold stiffness and micropore structure, which in turn influenced the cell loading capacity of the scaffold. Because material stiffness and topography are known to impact cell viability and fate, understanding the effect of scaffold fabrication parameters on mechanical and structural properties is critical to optimizing cell scaffolds for specific applications.
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