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Investigating the physical characteristics and cellular interplay on 3D-printed scaffolds depending on the incorporated silica size for hard tissue regeneration

Gi Hoon Yang, MyungGu Yeo, Eun‐Jeong Choi, Donggu Kang, Minseong Kim, Yunjoo Nam, So‐Jung Gwak, Hye Hyun Yoo, Min-Jeong Park, Bongsu Jung, Woonhyeok Jeong, Hojun Jeon

2021Materials & Design17 citationsDOIOpen Access PDF

Abstract

Silica has been widely used in bone tissue regeneration which is known to increase the bone mineral density and reduce bone resorption. In this study, surface modified silica particles with different sizes (100, 500, and 800 nm) were incorporated with polycaprolactone (PCL) to study the influence of silica particle size on physical and biological properties. Controversial results were observed between the physical and biological properties. In terms of physical properties including surface roughness, hydrophilicity, and mechanical strength, the PCL scaffold with 800 nm-sized particles showed significantly enhanced results. However, the scaffold with 100 nm-sized particles significantly upregulated the biological properties such as human mesenchymal stem cell adhesion, proliferation, and differentiation. This was also relevant for the in vivo results. Altogether, the results proved that the silica particle size influence the physical and biological properties of the PCL scaffold.

Topics & Concepts

Materials scienceScaffoldParticle sizePolycaprolactoneBone tissueResorptionAdhesionBiomedical engineeringSurface roughnessRegeneration (biology)NanotechnologyComposite materialChemical engineeringPolymerPathologyBiologyCell biologyEngineeringMedicineBone Tissue Engineering Materials3D Printing in Biomedical ResearchAdditive Manufacturing and 3D Printing Technologies
Investigating the physical characteristics and cellular interplay on 3D-printed scaffolds depending on the incorporated silica size for hard tissue regeneration | Litcius