Objective To investigate the latest development of tissue engineeredregenerative medicine in industrialization, with the intention to direct work in practical area. Methods A complete insight of regenerative medicine in industrialization was obtained through referring to update publications, visiting related websites, as well as learning from practical experience. Results The aerial view of the future of regenerative medicine was got based on knowledge of four different tissue engineering projects. Conclusion All present efforts should be devoted to regenerative medicine area meeting the industrialized trends.
Objective To review the latest development of amniotic fluid-derived stem cells (AFSCs) in regenerative medicine, and to discuss issues related to the studies in the field of AFSCs. Methods The recent articles about AFSCs were extensively reviewed. The important knowledge of AFSCs was introduced in the field of regenerative medicine, and the basic and clinical researches of AFSCs were summarized and discussed. Results Currently, it is confirmed that AFSCs have a multi-directional differentiation capacity, therefore, they have a wide application prospect in regenerative medicine, anti-tumor, and other fields. Conclusion AFSCs will become one of the ideal seed cells in the field of regenerative medicine with extensive research value because of the advantages of easy amniotic fluid sampling, little maternal and child trauma, no tumorigenesis, and no ethical restrictions.
Objective To summarize the developmental process of biomedical materials and regenerative medicine. Methods After reviewing and analyzing the literature concerned, we put forward the developmental direction of biomedical materials and regenerative medicine in the future. Results Biomedical materials developed from the first and second-generations to the third-generation in the 1990s. Regenerative medicine was able to help the injured tissues and organs to be regenerated by the use of the capability of healing themselves. This kind of medicine included the technologies of the stem cells and the cloning, the tissue engineering, the substitute tissues and organs, xenotransplantation and soon. Conclusion The third-generation biomaterials possess the following two properties: degradation and bioactivity; and they can help the body heal itself once implanted. Regenerative medicine is a rapidly advancing field that opens a new and exciting opportunity for completely revolutionary therapeutic modalities and technologies.
Abstract: The amniotic fluidderived stem cells (AFSC) possess considerable advantageous characteristics including high proliferation potential, easy availability, low immunogenicity and oncogenicity,and accordance with medical ethnics. Moreover, they do not require the sacrifice of human embryos for their isolation and the cells can differentiate into all three kinds of germs. Accordingly,they initiate a new and very promising field in stem cell research and they will be a potential source of stem cells for therapies related to regeneration medicine of cardiovascular diseases. The research about the AFSC utilization in cardiovascular diseases is just started. Though there were some exciting breakthroughs, there still remain many challenges. In the article,we will discuss AFSC characteristics, influence of amniotic fluid harvesting time on stem cells, isolation and purification, emphasizing mainly on the potential of AFSC differentiation into cardiovascular cells, current situation and problems in this field.
【Abstract】 Objective To review the recent progress of cell therapy in cl inical appl ications. Methods Therecent l iterature about cell therapy in cl inical appl ications was extensively reviewed. Results Based on the advances in cell biology, especially the rapid progress in stem cell biology, an increasing number of cl inical trials about cell therapy for management of various diseases, such as cardiovascular system diseases, neural system diseases, musculo-skeletal diseases, diabetes, stress urinary incontinence, and others, had been reported with encouraging results. All these showed that cell therapy had great potentials in cl inical appl ication. Conclusion Cell therapy provides a novel approach for the treatment of many human diseases. However, the mechanism remains to be fully elucidated.
Objective To review the development of the liver stem cell transplant for the liver regenerative treatment. Methods The transplantationrelated articles about the stem cell classification, repairing mechanisms, administration routes, and existing problems in the liver regenerative therapies reported in the latest literature were extensively reviewed. Results The related liverrepairing stem cells were found to be inside and outside the liver, i.e., the hepatic stem cells and the nonhepatic stem cells. They could repair the liver by the mechanism of the cell fusion or the celltransdifferentiation. The stem cells could be administrated via the portal vein. However, the application of the liver stem cell transplant was restricted by many related clinical problems. Conclusion Further studies are still needed for an improvement of the clinical feasibility for the stem cell transplantation, especially for the liver stem cell transplantation.
In recent years, regenerative medical technology and modern rehabilitation technology complement each other and develop rapidly. Regenerative rehabilitation with tissue regeneration and functional recovery as the core concept arises at the historic moment. Regenerative rehabilitation can quickly repair damaged or diseased tissues and organs, and restore or improve the function of patients to the greatest extent. This paper introduces the origin and development of regenerative rehabilitation, discusses the research progress and significance of related strategies from three aspects of neurological, motor and circulatory diseases, and stress the importance of regenerative rehabilitation in helping patients to obtain the best curative effect.
Objective To review the biochemical characteristics, appl ication progress, and prospects of the adiposederived stem cells (ADSCs). Methods The recent original experimental and cl inical l iterature about ADSCs was extensively reviewed and analyzed. Results ADSCs can be readily harvested in large numbers from adipose tissue with properties of stable prol iferation and potential differentiation in vitro. Significant progress of ADSCs is made in the animal experimentand the cl inical appl ication. It has been widely used in the cl inical treatment of cardiovascular disease, metabol ic disease, encephalopathy, and tissue engineering repair. Conclusion ADSCs have gradually replaced bone marrow mesenchymal stem cells and become the focused hot spot of regenerative medicine and stem cells.
ObjectiveTo summarize the progress of the roles and mechanisms of various types of stem cell-based treatments and their combination therapies in both animal studies and clinical trials of lymphedema. MethodsThe literature on stem cell-based treatments for lymphedema in recent years at home and abroad was extensively reviewed, and the animal studies and clinical trials on different types of stem cells for lymphedema were summarized.ResultsVarious types of stem cells have shown certain effects in animal studies and clinical trials on the treatment of lymphedema, mainly through local differentiation into lymphoid endothelial cells and paracrine cytokines with different functions. Current research focuses on two cell types, adipose derived stem cells and bone marrow mesenchymal stem cells, both of which have their own advantages and disadvantages, mainly reflected in the therapeutic effect of stem cells, the difficulty of obtaining stem cells and the content in vivo. In addition, stem cells can also play a synergistic role in combination with other treatments, such as conservative treatment, surgical intervention, cytokines, biological scaffolds, and so on. However, it is still limited to the basic research stage, and only a small number of studies have completed clinical trials. ConclusionStem cells have great transformation potential in the treatment of lymphedema, but there is no unified standard in the selection of cell types, the amount of transplanted cells, and the timing of transplantation.