Hydroxyapatite scaffold pore architecture effects in large bone defects in vivo.

To examine the effect of scaffold pore size on bone regeneration within hydroxyapatite scaffolds in large segmental defects, this study evaluated two porous interconnected architectures having similar porosity and strut thickness but different pore sizes. Using a 10 mm segmental rabbit radius defect model, a bilayer scaffold architecture mimicking the cortical-cancellous organization of bone (pore size 200 µm outer layer, 450 µm inner layer) was compared to a purely trabecular-like architecture (pore size 340 µm) and an untreated defect. Bone regeneration was measured using micro-computed tomography and histology after four and eight weeks of in vivo implantation, and the mechanical strength of the defect site after eight weeks' implantation was assessed using flexural testing.

Guided bone regeneration in long-bone defects with a structural hydroxyapatite graft and collagen membrane.

There are few synthetic graft alternatives to treat large long-bone defects resulting from trauma or disease that do not incorporate osteogenic or osteoinductive factors. The aim of this study was to test the additional benefit of including a permeable collagen membrane guide in conjunction with a preformed porous hydroxyapatite bone graft to serve as an improved osteoconductive scaffold for bone regeneration. A 10-mm-segmental long-bone defect model in the rabbit radius was used.

Evaluation of BMP-2 tethered polyelectrolyte coatings on hydroxyapatite scaffolds in vivo.

The goal of this in vivo study was to evaluate the osteoinductive and angio-inductive properties of a porous hydroxyapatite (HAp) scaffold with immobilized recombinant bone morphogenetic protein-2 (rhBMP-2) on the surface. It was hypothesized in this study that the use of a rhBMP-2 incorporated polyelectrolyte coating on the HAp scaffold would allow for controlled exposure of rhBMP-2 into the tissue and would provide a sound platform for tissue growth. The scaffolds were characterized for porosity and interconnectivity using pycnometry, scanning electron microscopy and micro-ct.