Preparation of bone marrow cells-derived extracellular matrix and its microstructure and composition / 中国组织工程研究

ABSTRACT

BACKGROUND:Extracellular matrix can simulate microenvironment and make the stem cells proliferate maintaining the characteristics of stem cells wel in vitro. OBJECTIVE:To prepare the extracellular matrix from human bone marrow cells and to analyze its microstructure and composition preliminarily. METHODS:Human bone marrow cells of passage 4 were cultured for 14 days, and the induction medium was used during the last 8 days. After decellularization, cells were removed to prepare human bone marrow cells-derived extracellular matrix. The surface morphology of human bone marrow cells-derived extracellular matrix was observed by inverted microscope and scanning electron microscope. Changes of col agen I and biglycan before and after decellularization were observed by immunofluorescence staining. Human periodontal ligament stem cells were seeded onto human bone marrow cells-derived extracellular matrix, fibronectin coated 6-wel plate and normal culture plate to compare the influence of different matrix on cellmorphology and adhesion. RESULTS AND CONCLUSION:We obtained intact human bone marrow cells-derived extracellular matrix by chemical combined with physical decellularization. The structure and amount of col agen I and biglycan had not been compromised dramatical y after decellularization. Human periodontal ligament stem cells growing on the human bone marrow cells-derived extracellular matrix developed in accordance with the orbit of the extracellular matrix, differing from the original cellmorphology. There were more human periodontal ligament stem cells adhering to the extracellular matrix during the same time. These findings indicate that effective decellularization can produce intact the extracellular matrix membrane without destroying its microstructure. Extracellular matrix protein is not compromised due to decellularization. The extracellular matrix affects cellmorphology and promotes celladhesion. We can use the extracellular matrix model to simulate stem cellmicroenvironment and thereafter, acquire a large number of adult stem cells with high quality in vitro.