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@#ObjectiveTo test and verify whether Ba-alginate-Poly-L-Ornithine-Alginate microcapsules(B-PLO-A) can improve the physical properties and biocompatibility of the traditional BPA microcapsules.MethodsThe B-PLO-A and Ba-alginate-Poly-L-lysine-alginate(B-PLL-A) microcapsules were made by the static generator. The physical property of the microcapsules was evaluated by observing the morphological changes of the microcapsules in the hypotonic environment, changes in diameter of microcapsules in vitro culture and calculating broken microcapsules ratio by shaking method. The biocompatibility was observed by transplanting into peritoneal cavity of rat.ResultsB-PLO-A microcapsules are stronger and more stable in a hypotonic environment than B-PLL-A microcapsules. After 96 h mechanism shaking, the unbroken microcapsules ratio of B-PLO-A and B-PLL-A microcapsules were (99.3±1.0)% and (96.2±1.5)% respectively. The microcapsules were retrieved from peritoneal cavity of rat at 2, 4 and 8 weeks after transplantation, most of the microcapsules were of integrity, rotundity, and surface smooth without obviously bundled by connective tissue. 8 weeks after transplantation the intact microcapsules ratio of B-PLO-A and B-PLL-A microcapsules were (97.3±2.1)% and (95.4±2.4)% respectively.ConclusionB-PLO-A microcapsules as a whole have bettermechanical strength compared with B-PLL-A microcapsules, while maintaining a good biocompatibility.
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@#Objective To reconstruct tissue-engineered 3D bronchial model using human bronchial epithelial cells and human embryo lung fibroblast as seeding cells, and liquid collagen mixed Matrigel as scaffold. Methods Human bronchial epithelial cells and human embryo lung fibroblast were mixed with liquid collagen supplementing with matrigel and casted in 12-wells plate to reconstruct cells-collagen sheet. Macroscopic observation, phase-contrast microscopy observation, routine HE staining and immunohistochemistry staining(CK ets) were employed to assess the engineered 3D model. Results We reconstructed engineered 3D bronchial model successfully in vitro by tissue engineering techniques and exerted static stretch onto the collagen sheet. From Macroscopic observation, we gained contracted well sheet. We also observed network structure in phase-contrast microscopy meanwhile the viability of cells was fine. HE staining showed the formation of 3D network structure. The immunohistochemistry staining of CK and Vimentin were positive.Conclusion We reconstructed engineered 3D bronchial model successfully in vitro and seeding cells could implement polarity growing in the scaffold materials then gained the network structure.
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Proteome research has become a new hot spot in the post-genome era. High-resolution two-dimensional gel electrophoresis (2-DE), which provides the most comprehensive analysis system of the whole proteome, was highly improved in recent years. With the development of computer techniques, the powerful and user-friendly image analysis systems appeared to help high-throughput, large-scale proteomic studies. Using new generation two-dimensional image analysis software, ImageMaster 2D Elite, the 2D gels of proteins extracted from cultured Schwann’s cells were processed. The analysis procedure, including image acquirement, spot detection, match, background subtraction, pI/Mr calibration, analysis results report and database query, were reported and discussed.