[Influences of induced membranes on heterotopic bone formation within an osteo-inductive complex. Experimental study in rabbits]. / Influence des membranes induites sur l'ostéogenèse hétérotopique au sein d'un complexe ostéo-inducteur. Etude expérimentale chez le lapin.

UNLABELLED: Based on a new concept, a procedure combining induced membranes and cancellous autografts allows the reconstruction of wide diaphyseal defects. To date, this procedure is limited by the amount of cancellous bone available from the patient and by the related morbidity at the donor site. The aim of this study was to evaluate the biological effect of induced membranes on a cylindrical-shaped ceramic implants loaded with OP-1 in heterotopic site. MATERIALS AND METHODS: Sixty hydroxyapatite tricalcium phosphate (HA-TCP) implants, 20 of which being loaded with a bone growth factor (rhOP-1) were inserted either in a subcutaneous tunnel or within a previously induced membrane on the back of rabbits. There were two time-points at four and 16 weeks. Implants were investigated at three different levels (extremities and middle). RESULTS: None of the untreated implants showed any evidence of bone formation. Implants inserted in an induced membrane presented with less resorption. Bone ingrowth within the pores of the materials was significantly higher when the implants were inserted into the induced membrane whatever the time-point considered. CONCLUSION: The membrane seems to play the role it was assigned, i.e. to protect and revascularize the implant, thus favouring osteogenesis that occurs in 80% of the implants after four months.

In-vitro and in-vivo design and validation of an injectable polysaccharide-hydroxyapatite composite material for sinus floor augmentation.

OBJECTIVE: Polysaccharide-based composite matrices consisting of natural polysaccharides, pullulan and dextran supplemented with hydroxyapatite (Matrix-HA) have recently been developed. The principal objective of this study was to evaluate the capacities of this composite material to promote new bone formation in a sinus lift model in the sheep. Secondary objectives were to evaluate in vitro properties of the material regarding cell adhesion and proliferation. METHODS: In this report, once such composite matrix was prepared as injectable beads after dispersion in a physiological buffer, and evaluated using a large animal model (sheep) for a sinus lift procedure. RESULTS: In vitro studies revealed that these microbeads (250-550µm in diameter) allow vascular cell adhesion and proliferation of Endothelial Cells (EC) after 1 and 7 days of culture. In vivo studies were performed in 12 adult sheep, and newly formed tissue was analyzed by Cone Beam Computed Tomography (CBCT scanning electron microscopy (SEM) and by histology 3 and 6 months post-implantation. CBCT analyses at the implantation time revealed the radiolucent properties of these matrices. Quantitative analysis showed an increase of a dense mineralized tissue in the Matrix-HA group up to 3 months of implantation. The mineralized volume over total volume after 6 months reached comparable values to those obtained for Bio-Oss® used as positive control. Histological examination confirmed that the Matrix-HA did not induce any long term inflammatory events, and promoted direct contact between the osteoid tissue and lamellar bone structures and beads. After 6 months, we observed a dense network of osteocytes surrounding both biomaterials as well as a newly vascularized formed tissue in close contact to the biomaterials. SIGNIFICANCE: In conclusion, the absence of animal components in Matrix-HA, the osteoconductive property of Matrix-HA in sheep, resulting in a dense bone and vascularized tissue, and the initial radiolucent property to follow graft integration offer great promises of this composite material for clinical use.