Abstract
Skeletal sequels of traumatisms, diseases or surgery often lead to bone defects that fail to self-repair. Although the gold standard for bone reconstruction remains the autologous bone graft (ABG), it however exhibits some drawbacks and bone substitutes developed to replace ABG are still far for having its bone regeneration capacity. Herein, we aim to assess a new injectable allogeneic bone substitute (AlloBS) for bone reconstruction. Decellularized and viro-inactivated human femoral heads were crushed then sifted to obtain cortico-spongious powders (CSP). CSP were then partly demineralized and heated, resulting in AlloBS composed of particles consisting in a mineralized core surrounded by demineralized bone matrix, engulfed in a collagen I gelatin. Calvarial defects (5mm in diameter, n=6/condition) in syngeneic Lewis1A rats were filled with CSP, AlloBS±TBM (total bone marrow), BCP (biphasic calcium phosphate)±TBM or left unfilled (control). After 7 weeks, the mineral volume/total volume (MV/TV) ratios were measured by µCT and Movat's pentachrome staining were performed on undemineralized frontal sections. The MV/TV ratios in defects filled with CSP, AlloBS or BCP were equivalent, whereas the MV/TV ratio was higher in AlloBS+TBM compared to CSP, AlloBS or BCP (p<0.01; Mann-Whitney). Histological analyses exhibited a collagen-rich matrix in all the defects, and osteoid at the surface of all implanted biomaterials. Our data indicates that AlloBS is a promising candidate for bone reconstruction, with ease of manipulation, injectability and substantial osteogenic capacity. Further experiments in larger animal models are under consideration to assess whether AlloBS may be a relevant clinical alternative to ABG.
