| Abstract: | In bone regenerative engineering, the biomechanical performance of the scaffold at the bone-tissue interface is a key consideration. The evaluation of this parameter is a crucial step in designing, optimizing and manufacturing of bone substitute materials for clinical application, but is as yet comparatively unexplored. To this end, we utilized a novel polymer-assisted method to fabricate a three-dimensional (3D) Polycaprolactone/β-Tricalcium phosphate scaffold. The compressive modulus was measured and the data used to inform finite element analysis. The scaffolds achieved a maximum compressive moduli of 151 MPa, close to that of cortical bone. Further computational simulations were performed to determine the stresses and local scaffold adaptation profile, using data from computer tomography scans of the mandible. Local stresses were simulated based on the density changes in new bone forming in the scaffold at different stages of healing. The stress distribution in the mandible, scaffold center and scaffold interface were explored for a static load of 200 N, which corresponds to the load of adult mastication near the incisors. The analysis revealed that the maximum cross-sectional stress at the scaffold center and at the scaffold interface was 2.7 and 4.12 MPa respectively. The majority of the stress was localized in the bone of the mandible, with the scaffold bearing minimal loading at the start, but more over time as infiltration of more new bone progressed. |
