Treatment of segmental bone loss remains a major challenge in orthopaedic surgery. This study evaluated the healing potential of a series of highly porous tissue engineering scaffolds with the current clinical gold standard. We compare healing of collagen-glycosaminoglycan (CG) and collagen micro-hydroxyapatite (CHA) scaffolds, with and without recombinant bone morphogenetic protein-2 (BMP2), with autogenous bone graft (ABG) in the healing of a 15mm rabbit radius defect, which were filled with either CG scaffold, CHA scaffold, CG-BMP2, CHA-BMP2 or ABG. Serial radiographs and micro-computed tomography (µCT) at six week radiographs demonstrated complete defect bridging with callus using CHA and CG-BMP2 while the CHA-BMP2 was already in an advanced state of healing with cortical remodeling. By sixteen weeks CHA, CG-BMP2 and ABG all had advanced healing with cortical remodeling while CHA-BMP2 had complete anatomic healing. Quantitative histomorphometry values demonstrated similarly high healing levels of healing in CHA, CG-BMP2 and ABG with highest overall values in the CHA-BMP2 group. Thus, treatment of a critical sized, weight bearing, rabbit radius defect with a CHA scaffold can result in full cortical bridging with medullary cavity development. In addition, a CHA-BMP2 combination can result in fully mature, anatomic healing. The use of an
Traditionally, the gold standard for bone grafting has been either autografts or allografts. Whilst autografts are still widely used, drawbacks such as donor site morbidity are shifting the market rapidly toward the use of orthobiologic bone graft substitutes. This study investigated the in vivo performance of a novel (W02008096334) collagen-hydroxyapatite (CHA) bone graft substitute material as an osteoinductive tissue engineering scaffold. This highly porous CHA scaffold offers significantly increased mechanical strength over collagen-only scaffolds while still exhibiting an extremely high porosity (≈ 99%), and an osteoinductive hydroxyapatite phase [1]. This study assessed the ability of the CHA scaffolds to heal critical-sized (15 mm) long bone segmental defects in vivo, as a viable alternative to autologous bone grafts. Collagen-HA (CHA) composite scaffolds were fabricated based on a previously-described freeze-drying technique [1]. After freeze-drying, these scaffolds were subjected to a dehydrothermal treatment and subsequently chemically crosslinked using EDAC. In vivo performance was assessed using a critical size segmental radial defect (15 mm) introduced into 16 young adult New Zealand White Rabbits under Irish Government license. Animals were divided into three groups; (i) an empty defect group (negative control), (ii) an autogenous bone graft group (positive control) and (iii) a CHA scaffold group (CHA). Segmental defect healing in all animals was assessed using plain X-Ray analysis, at four time-points (0, 6, 12 and 16 weeks). MicroCT and histological analysis were carried out at week 16.Purpose
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