• Leppik, Liudmila
• Oliveira, Karla Mychellyne Costa
• Marzi, Ingo
• Frank, Johannes
• Dörsam, Edgar
• Henrich, Dirk
• Schätzlein, Eva
• Blaeser, Andreas
• Zoghool, Shahed Al
• Ritz, Ulrike
• Söhling, Nicolas
• Neijhoft, Jonas

Abstract

<jats:p>Three-dimensional (3D) printing is considered a key technology in the production of customized scaffolds for bone tissue engineering. In a previous work, we developed a 3D printable, osteoconductive, hierarchical organized scaffold system. The scaffold material should be osteoinductive. Polylactic acid (PLA) (polymer)/Bioglass (BG) (mineral/ion source) composite materials are promising. Previous studies of PLA/BG composites never exceed BG fractions of 10%, as increase of bioactive BG component negatively affects the printability of the composite material. Here, we test a novel, 3D printable PLA/BG composite with BG fractions up to 20% for its biological activity in vitro. PLA/BG filaments suitable for microstructure 3D printing were spun and the effect of different BG contents (5%, 10%, and 20%) in this material on mesenchymal stem cell (MSC) activity was tested in vitro. Our results showed that all tested composites are biocompatible. MSC cell adherence and metabolic activity increase with increasing BG content. The presence of BG component in scaffold has only slight effect on osteogenic gene expression, but it has significant suppressive effect on the expression of inflammatory genes in MSC. In addition, the material did not provoke any significant inflammatory response in whole-blood stimulation assay. The results show that by increasing the BG content, the bioactivity can be further enhanced.</jats:p>

Topics

• impedance spectroscopy
• microstructure
• mineral
• polymer
• composite
• bioactivity