| Biocompatible scaffolds that replicate the structure and function of bone would be ideal bone substitutes for structural bone loss, provided they have the requisite mechanical properties for reliable long-term loading. In this dissertation, strong porous scaffolds of silicate 13-93 bioactive glass, created with two different microstructures, were evaluated to determine their mechanical properties and their capacity to regenerate bone in a rat calvarial defect model. Scaffolds with an oriented microstructure of columnar pores were prepared by unidirectional freezing of camphene-based suspensions, followed by thermal annealing and sintering. By optimizing the freezing conditions, annealing time, and sintering temperature, constructs (porosity = 50 +/- 4%; average pore diameter = 100 mum) were created with a compressive strength of 47 +/- 5 MPa and an elastic modulus of 11 +/- 3 GPa (in the orientation direction). New bone formation in the pore space of the scaffolds increased from 37% at 12 weeks to 55% at 24 weeks in vivo. Scaffolds with grid-like microstructure (porosity= 47 +/- 1%; pore width = 300 mum), prepared by a robotic deposition (robocasting) technique, had a compressive strength (86 +/- 9 MPa) and an elastic modulus (13 +/- 2 GPa) comparable to human cortical bone, a Weibull modulus of 12, and excellent fatigue resistance in compression. Bone regeneration in the as-fabricated scaffolds in vivo (32% at 6 weeks) was significantly enhanced (to ∼60%) by a surface treatment in an aqueous phosphate solution or loading the surface-treated scaffolds with bone morphogenetic protein-2 (1 mug/defect), prior to implantation. Scaffolds of 13-93 bioactive glass with a grid-like microstructure prepared by robocasting, showing better mechanical properties and a greater capacity to support bone formation, are more promising in structural bone repair. |
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