Bioresorbable materials offer the potential of developing fracture fixation plates with similar properties to bone thereby minimising the “stress shielding” associated with metal plates and obviating the need for implant removal. Phosphate glass fibre reinforced (PGF)-polylactic acid (PLA) composites are bioresorbable and have demonstrated sufficient retention of mechanical properties to enable load bearing applications. To determine the potential in vivo “stress shielding” effects of a novel PGF reinforced PLA composite plate in an animal model.Background
Aim
Bioresorbable materials offer the potential of developing fracture fixation plates with similar mechanical properties to bone thereby minimizing stress shielding and obviating the need for implant removal. To determine the in vivo degradation profile of a novel phosphate glass fibre composite bioresorbable plate and effects on the underlying bone.Background
Aim
