Isolation, expansion and adipogenic differentiation of human keloid-derived precursor cells / 中华医学美学美容杂志

Objective To explore the isolation,amplification methods and adipogenic differentiation under specific culture medium of human keloid-derived precursor cell (KPC) in vitro,in order to study their possibility of being new seed cells of tissue engineering fat.Methods KPCs were isolated from human keloid tissue of 4 different patients in our hospital and were cultured in the modified L-DMEM culture medium.Their cloning efficiency and growth curve were tested.The subcultured cells were tested of the mesenchymal stem cell (MSC)-related gene expression by flow cytometry.In addition,they were cultured in H-DMEM medium (containing 1 μmol/L dexamethasone,0.5 mmol/L 3-isobutyl-1-methyl-xanthine 10 mg/L of bovine insulin,100 mmol/L indomethacin,and 10 ％ FBS)and were later observed in oil red O staining under phase contrast microscope to determine whether lipid droplets generation was formed,using skin-derived precursors (SKP) as control.Results More than 95 ％ KPC expressed many antigens of MSC,such as CD29,CD44,CD90 and CD105 while few of them expressed CD34,CD45(1.0 ％-2.5 ％).And the cells increased in size gradually after inducted the same time,changing from spindle into round or polygonal in shape.The lipid droplets were seen in 72 hours and expressed a positive rate of 78.6 ％ in Day 19 in oil red O staining while the same rate was 54.6 ％ in SKP.Conclusions Human keloid-derived precursor cells can express a variety of MSC-related surface markers without expressing hematopoietic stem cell (HSC) related markers.Furthermore,they can be differentiated into fat cells under certain conditions,which may make them as a new source of seed cells for tissue engineering fat.

Application of synthetic and natural scaffold materials in skin tissue engineering / 中国组织工程研究

There are many kinds of scaffolds used in the field of tissue engineering, which can be divided into natural biological scaffolds and synthetic scaffolds. This paper summarizes the latest advances of research on scaffolds of skin tissue engineering and review amounts of related literatures on this field. The result shows that natural biological scaffolds can provide a better three-dimensional space for the adhesion and generation of cultured cells. These scaffolds have an extensive application in skin tissue engineering.