Objective To review the current researches of scaffold materials for skeletal muscle tissue engineering, to predict the development trend of scaffold materials in skeletal muscle tissue engineering in future. Methods The related l iterature on skeletal muscle tissue engineering, involving categories and properties of scaffold materials, preparative techniqueand biocompatibil ity, was summarized and analyzed. Results Various scaffold materials were used in skeletal muscle tissue engineering, including inorganic biomaterials, biodegradable polymers, natural biomaterial, and biomedical composites. According to different needs of the research, various scaffolds were prepared due to different biomaterials, preparative techniques, and surface modifications. Conclusion The development trend and perspective of skeletal muscle tissue engineering are the use of composite materials, and the preparation of composite scaffolds and surface modification according to the specific functions of scaffolds.
Objective To introduce the research advances of scaffold materials of intervertebral disc tissue engineering. Methods The recent original articlesabout the scaffolds in intervertebral disc tissue engineering were extensively reviewed. Results At present, agarose, alginate gel, collagentype Ⅰ, PLA, PGAare still major scaffold materials for intervertebral disc tissue engineering because of their good biocompatibility. Conclusion It is one of the popular studies on current intervertebral disc tissue engineering to explore the ideal scaffold materials.
Objective To observe the ability to repair bilateralradius bone defect with the composite of β-tricalciumphosphate(βTCP),hyaluronic acid(HA),type I collagen(COL-Ⅰ) and induced marrow stromal cells(MSCs), and to investigate the feasibility of the composite as a bone substitute material.Methods The MSCs of the New Zealand white rabbits were induced into ostoblasts, then combined with β-TCP, HA and COL-Ⅰ. Thirty New Zealand white rabbits were made the bilateral radius bone defects of 2 cm and divided into groups A, B and C. After 8 weeks, β-TCP-HA-COL-Ⅰ-MSCs (group A, n=27 sides), autograft (group B, n=27 sides)andno implant(group C as control, n=6 sides)were implanted into the areas ofbilateral radius bone defects, respectively. The structure of the composite was observed by scanning electron microscope. The repairing effect was observed by gross, histomorphology, X-ray examination, and the degradation rate of inorganic substance at 4, 8 and 12 weeks. The ostogenic area and biomechanics ofgroup A were compared with those of group B at 12 weeks.Results The MSCs could stably grow in vitro, relatively rapidly proliferated, and could be induced into the ostoblasts.The composite was porous. The results of gross, histomorphology and X-ray showed that the bone defects were perfectly repaired in group A and group B, but not in group C. The ostogenic area or biomechanics had no statistically significant difference between groups A and B(Pgt;0.05). The weight of inorganic substance in group A were 75% ,57% and 42% at 4,8,12 weeks, respectively.Conclusion MSCs can be used as seedcells in the bone tissue engineering. The composite has porous structure, no reactions of toxicity to the tissue and rapid degradation, and it is an ideal carrier of seed cells.The β-TCP-HA-COL-Ⅰ-MSCs composite has the high ability of repairing bone defect and can serve as an autograft substitute material.