ABSTRACT
Tissue engineering skin has a wide application prospect on the clinical treatment of all sorts of skin defect, especially large area burn. The shortage of seed cells and their function improvement are the main problems in this field. The existing seed cells of tissue engineering skin are difficult to meet the needs of clinical application due to the limitations of acquisition, proliferation, and aging. Subsequently, the generation of induced pluripotent stem cells (iPSCs) provides a safe and efficient cell source for tissue engineering skin. Our article focuses on the origin of iPSCs and its characteristics of differentiating into keratinocytes, fibroblasts, melanocytes, vascular smooth muscle cells, nerve cells, and hair follicle, and discusses the main problems and prospects of iPSCs in establishment of tissue engineering skin and application in wound repair.
ABSTRACT
Since its establishment for 60 years, Department of Burns of the Second Affiliated Hospital of Zhejiang University School of Medicine has grown into a famous regional burn center in China under the leading of the pioneers and through the efforts of several generations. The department has distinctive disciplinary features in burn care, nutritional support, scar prevention and treatments, standard management of chronic wound, and skin tissue engineering research, making positive contribution to the development of burn medicine in China.
ABSTRACT
Three-dimensional (3D) printing is a low-cost, high-efficiency production method, which can reduce the current cost and increase the profitability of skin repair material industry nowadays, and develop products with better performance. The 3D printing technology commonly used in the preparation of skin repair materials includes fused deposition molding technology and 3D bioprinting technology. Fused deposition molding technology has the advantages of simple and light equipment, but insufficient material selection. 3D bioprinting technology has more materials to choose from, but the equipment is cumbersome and expensive. In recent years, research on both technologies has focused on the development and application of materials. This article details the principles of fused deposition modeling and 3D bioprinting, research advances in wound dressings and tissue engineering skin production, and future developments in 3D printing on skin tissue repair, including cosmetic restoration and biomimetic tissue engineering. Also, this review prospects the development of 3D printing technology in skin tissue repairment.
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Objective To detect the characteristics and in vitro cell compatibility of human acellular dermal matrix (ADM) with the improved method.Methods Cell components of healthy human skins were removed by the improved method and the traditional method respectively.The porosity, degradation time in vitro of the ADM prepared by two methods and the cytotoxicity of the material infiltration liquid with the improved method on the adipose derived stem cells were detected.HE staining was used to detect the residual of the cells, the integrity of collagen and cell biocompatibility.Scanning electron microscopy (SEM) was used to detect the pore size.Results Both the two methods could completely remove the cells, and maintain the integrity of the collagen scaffold;The porosity of ADM with the improved method was higher (93.1±1.02)% than that of traditional method (74.27±2.04)% (P<0.05);There was no significant difference in the cytotoxicity and in vitro degradation time between the two kinds of ADM;While pore diameter of the improved method was significantly higher [(181.21±66.9) μm] than that [(102.38±15.63) μm] in dermal reticular surface with the traditonal method (P<0.05).Conclusions There is no obvious cytotoxicity of the ADM with the improved method, and therefore it is more suitable for cell adhesion growth with higher porosity and larger pore size.
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Objective To establish the three-dimensional culture model of the human skin squamous-celled carcinoma ,and isolate the highly invasive cell subsets ,and compare their biological characteristics .Methods By using the composite chitosan tissue engi-neering skin ,the three-dimensional culture model of the human skin squamous-celled carcinoma was successfully established , through digestion ,we divided and got the high-invasive squamous carcinoma cells subsets .After that ,the different invasive proper-ties of subpopulations of cells in nude mice tumor effects were compared .Results Different concentrations of cinnamaldehyde and interferon on skin squamous-celled carcinoma cell proliferation inhibition had statistical significance (P<0 .01) ,the different invasive characteristics of skin squamous cells carcinoma between subpopulations of cells proliferation inhibition also was statistically signifi-cant(P<0 .01) ,and the two different invasive properties of subpopulations of cells in the tumor characteristics also had statistical significance(P<0 .01) .Conclusion We established the three-dimensional culture model of the human skin squamous-celled carcino-ma successfully ,by using this model ,we could screen the higher invasive cells subsets .
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Objective: To investigate the applied feasibility of scaffold with modified PLA (Polymer of lactic acid) in tissue engineering. Methods:First, we adopted salting-in method to prepare porous foam scaffold. Then, we reconstructed tissue engineering skin by epidermal cells and fibroblasts combined with modified PLA. On the 14th day of cell culturing in vitro, we was a control. Results:The arfificial skin is composed of epidermis and dermis and similar to natural skin in appearance. The skin consists of fibroblasts and keratinocytes, which are in various proliferation and differentiation stages. Fibroblasts and keratinocytes distribute on the surface of polymer of lactic acid (PLA) and the number of fibroblast and keratinocyte increase. Conclusion:Dialdehyde starches (DAS) not only improve the function of PLA but also have good effects on cells. Moreover, it does not affect the growth and the metabolism of the cells. So it is feasible to use modified scaffold to construct tissue engineering skin.
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Objective: To investigate the applied feasibility of scaffold with modified PLA (Polymer of lactic acid) in tissue engineering. Methods:First, we adopted salting-in method to prepare porous foam scaffold. Then, we reconstructed tissue engineering skin by epidermal cells and fibroblasts combined with modified PLA. On the 14th day of cell culturing in vitro, we was a control. Results:The arfificial skin is composed of epidermis and dermis and similar to natural skin in appearance. The skin consists of fibroblasts and keratinocytes, which are in various proliferation and differentiation stages. Fibroblasts and keratinocytes distribute on the surface of polymer of lactic acid (PLA) and the number of fibroblast and keratinocyte increase. Conclusion:Dialdehyde starches (DAS) not only improve the function of PLA but also have good effects on cells. Moreover, it does not affect the growth and the metabolism of the cells. So it is feasible to use modified scaffold to construct tissue engineering skin.
ABSTRACT
Objective: To investigate the applied feasibility of scaffold with modified PLA (Polymer of lactic acid) in tissue engineering. Methods:First, we adopted salting-in method to prepare porous foam scaffold. Then, we reconstructed tissue engineering skin by epidermal cells and fibroblasts combined with modified PLA. On the 14th day of cell culturing in vitro, we was a control. Results:The arfificial skin is composed of epidermis and dermis and similar to natural skin in appearance. The skin consists of fibroblasts and keratinocytes, which are in various proliferation and differentiation stages. Fibroblasts and keratinocytes distribute on the surface of polymer of lactic acid (PLA) and the number of fibroblast and keratinocyte increase. Conclusion:Dialdehyde starches (DAS) not only improve the function of PLA but also have good effects on cells. Moreover, it does not affect the growth and the metabolism of the cells. So it is feasible to use modified scaffold to construct tissue engineering skin.