Mesenchymal stem cells (MSCs) hold great promise for bone regeneration. However, the power of mesenchymal stem cells has not been applied to structural bone allografts in clinical practice. This study designed a new strategy to enhance the efficiency of allografts for segmental bone regeneration. Isolated MSCs were cultured to form a cell sheet. The MSC sheet was then wrapped onto structural allografts. The assembled structures were cultured in vitro to evaluate the differentiation potential of MSC sheet. The assembled structures were implanted subcutaneously into nude mice as well as into the segmental radius defect of rabbits to investigate the efficiency of MSC sheets to repopulate allografts for bone repair. MSC sheets, upon assembling on bone grafts, showed similar differentiation properties to the in situ periosteum in vitro. After implantation the MSC sheets accelerated the repopulation of bone grafts in nude mice. Moreover, MSC sheets induced thicker cortical bone formation and more efficient graft-to-bone end fusion at the segmental bone defects in rabbits. This study thus presented a novel, more efficient, and practical strategy for large weight-bearing bone reconstruction by using MSC sheets to deliver large number of MSCs to repopulate the bone allografts.Key words: Mesenchymal stem cells; Bone allografts; Tissue engineering
INTRODUCTIONpromising results for bone tissue engineering (2,19,30). Despite the bone tissue engineering progress, the weak porous scaffolds are not suitable in reconstruction of At present, the most common biomaterials for segmental bone defects reconstruction are allogeneic cortilarge weight-bearing skeletal defects. As a result, few of the mesenchymal stem cell research achievements can cal bone grafts (e.g., cryopreserved bone grafts). However, the slow healing of allografts often results in graft be adapted to the bedside practice (26,29). The techniques of populating large numbers of profracture and poor clinical outcome. It was generally recognized that slow healing of allograft is likely due to genitor cells to weight-bearing allografts are thus desired to cover this gap between basic research and clinical the lack of live periosteal cells (12,27).Mesenchymal stem cells (MSCs) are multipotential practice. Currently, cell-seeding techniques employ either cell-gel composites or cell suspension to deliver cells capable of differentiating into various mesenchymal lineages such as bone, cartilage, adipocytes, tendon, cells into the scaffold (1,7,32). However, high porosity is required by these cell-seeding techniques, whereas and ligament (5,17,23,24). MSCs isolated from about 10 ml of bone marrow could be easily cultured and amplicortical bone grafts are too dense for cell distribution by physical infiltration. fied in vitro to yield billions of cells (9). A number of previous studies successfully utilized MSCs as seed cellsThe present study aims to help overcome the challenges of applying the power of MSCs to clinical large for cartilage and tendon repair in animal models (1...
