Description:
<jats:p>Synthetic materials such as bone substitutes are permanently under development for applications in orthopedic and trauma surgery. Our porous scaffolds were produced from ß-tricalcium phosphate (TCP) using the three dimensional (3D)-printing technology. After sintering the porosity and the pore size of the 3D printed scaffolds reached nearly 50 % and 500 µm, respectively. TCP scaffolds were additionally stabilized by infiltration with polylactic acid (PLA). Because PLA usually impeded cell adhesion we activated the composite surface with plasma polymerized allylamine in a low temperature plasma process. For cell investigations inside the scaffold we used a module system, where two porous discs can be horizontally fixed within a clamping ring. Thereby a 3D cell culture module with four levels and a maximal height of 10 mm was generated. Human MG-63 osteoblasts (ATCC) were seeded apically and placed in serum-containing DMEM. After 14 days of a static cell culture the cell ingrowth and mobility was analyzed by scanning electron microscopy. Osteoblast's initial adhesion and short time occupation of the surface is significantly improved on plasma polymer activated TCP surfaces, which could be a precondition for an enhanced colonization inside a calcium phosphate scaffold. Interestingly, the plasma functionalization of the pure TCP scaffold was possible and successful concerning cell acceptance.</jats:p>