[Effect of dual sustained-release nanofiber scaffolds embedded with BMP-2 protein nanospheres on the proliferation and differentiation of MC3T3-E1 cells].

Purpose: Electrospinning technology was used to construct PCL composite nanofiber scaffold material of BMP-2 sustained-release nanospheres, and the effect of this nanospheres on proliferation and differentiation of MC3T3-E1 cells was evaluated.

Methods: Solvent removal method and electrostatic self-assembly technology were used to prepare BMP-2 loaded chitosan nanospheres, the morphology, particle size and composition, BMP-2 protein encapsulation efficiency, and in vitro sustained release were tested. Electrospinning technology was ued to prepare PCL composite scaffold material containing BMP-2 nanospheres, and its morphology, hydrophilicity,and sustained release of BMP-2 protein were examined. In vitro cytology experiment was conducted to observe the growth of cells in the material, and the formation of ALP, related genes, and mineralized nodules during the process of osteogenic differentiation of the material were detected. SPSS 21.0 software package was used for statistical analysis.

Results: The nanospheres structure with stable structure was successfully prepared, with a high drug loading rate and sustained release of BMP-2. The PCL/BNPs scaffold material group had good hydrophilic properties and was conducive to cell proliferation and differentiation. The results of in vitro cell experiments showed that the cells spread well on the scaffold and the number of adhesions increased. ALP and related osteogenic genes COL1, OPN, RUNX2 increased, and the size and number of calcium nodules increased significantly.

Conclusions: The polycaprolactone composite fiber scaffold material of BMP-2 sustained-release nanospheres can provide a new choice for the development of bone tissue engineering.