Objective To summary the characteristics of adult stem cells and to introduce the definition and the features of stem cell disease.Methods Literature concerning adult stem cells and stem cell disease was extensively reviewed.Results Adult stem cells were localized in tissues and organs, and were able to generate function cells to replace cell loss during a lifetime of wear and tear. The stem cells had selfrenewal to maintain themselves and undergo aging within the lifespan of an organism. The dysfunction of stem cells was capable to cause diseases, which could be defined as stem cell disease in human. The disorder of self renewal and differentiation in stem cells could increase the cellular proliferation, produce proliferative diseases such as tumors. The stem cells with self renewal defect, differentiation blockage, or aged stem cells could not supply enough function cells for tissue refreshment. The defect of tissue refreshment caused degenerative diseases.Conclusion Studies on the stem cell self renew, differentiation, and aging can provide knowledge to understand the mechanism of stem cell diseases and develop technique to diagnose and treat these diseases.
OBJECTIVE: To explore the pluripotential and possible clinical application of adult stem cells. METHODS: The original articles on adult stem cells were extensively reviewed and the recent advances were summed up. RESULTS: Adult stem cells were located at different tissues of human beings and had the pluripotentiality of self-renewal and differentiation. Some adult stem cells, such as in marrow, nerve, muscle, fat, skin, liver, tissues, had the ability to differentiate into the unrelated cell type. CONCLUSION: The pluripotential, ubiquitous distribution and plasticity of adult stem cells offered a new way in regeneration medicine, such as cell therapy and tissue engineering.
Objective To observe the differentiation effect of rabbit amnion-derived stem cells (ADSC) induced into neural cells.Methods ADSC of New Zealand female rabbits were isolated and cultured. Its mRNA level of Fibronectin, Nestin and Vimentin were detected by real-time quantitative polymerase chain reaction. The selfreplication ability of ADSC was confirmed by monoclonal formation experiments. These ADSC were further induced into neural cells in vitro. Five days after induced differentiation, the expression of -tubulin and glial fibrillary acidic protein (GFAP) were detected by immunofluorescent staining. Results ADSC were separated from amnion tissue gradually after 24 hours. There were polygonal cells gathered around the amnion tissue at 72 hours, and were distributed compactly around the amnion at 120 hours. The morphology of cleavage daughter cells was basically the same as parent cells. ADSC has the ability of self-replication. The Nestin, Vimentin, Fibronectin mRNA expressions in ADSC were 15.79, 1.91, 7.65 times those in spleen cells. The differences were statistically significant(Z=-5.243, -3.972, -2.524; P<0.05). The beta;-tubulin expression was found in cytoplasm of most cells. The GFAP expression was found in cytoplasm in some cells. Conclusions ADSC has self-replication ability. It can be induced into neurons and neuroglial cells under the right conditions.
Objective To research the methods and techniques of SD rat bone marrow stromal cells (MSCs)culture in vitro and to provide a large number of MSCs for cell therapy. Methods Bone marrow from the femur and tibia of the early age SD rats was taken to culture to the passage 1-4 (P1-P4), its growth was observed and P3 cells were evaluated by HE staining and immunohistochemisty. Results The growing speed of P1-P3 was faster than that of P0, cells fusion was 85%-90% after 3-4 d and the cells were arranged in groups liked whirlpool shape or parallel; (3.4-3.6)×104/cm2 cells were gained and the total cell number of P1-P3 was 4.08×106, 2.44×107 and 2.85×108 respectively, the rate of trypan blue rejecting stained was 95%-97%. P4’s growing speed was slower than before, 1.42×109 in 3.0×104/cm2 cells were gained, and the rate of rejecting stained was 95%. P4-cell output was amplified nearly 2 000-fold higher than P0-cell. P3 immunohistochemical analysis indicated CD105+ cells 61.9%, CD44+ 45.4%, CD29+ 16.8%, CD45+ 8.2%, CD31+ 13.7%, CD34+ 8.3% and CD11b+ 1.5%, respectively. Conclusion The culture of whole bone marrow is suitable for a large number of MSCs provision in vitro, and can meet the needs of the cell therapy research.
There are over 8 million blind patients in China, 1/3 of them are suffered from retinal degeneration diseases. Stem cells transplantation can delay the photoreceptor cell degeneration or replace the dead photoreceptor cells, provides hopes for these patients. How to make enough seed cells is the major barrier for cell therapy. Good seed cells should be safe and with great pluripotency, and can be made from a wide range of sources, easy to be standardized and industrialized. Seed cells made from three-dimensional embryonic stem cells cultures can reach the above criteria, thus three-dimensional embryonic stem cell culture is a new strategy for making seed cells for cell treatment of blind diseases.
Retinal degeneration mainly include age-related macular degeneration, retinitispigmentosa and Stargardt’s disease. Although its expression is slightly different, its pathogenesis is photoreceptor cells and/or retinal pigment epithelial (RPE) cel1 damage or degeneration. Because of the 1ack of self-repairing and renewal of retinal photoreceptor cells and RPE cells, cell replacement therapy is one of the most effective methods for treating such diseases.The stem cells currently used for the treatment of retinal degeneration include embryonicstem cells (ESC) and various adult stem cells, such as retinal stem cells (RSC), induced pluripotent stem cells (iPSC). and mesenchyma1 stem cells (MSC). Understanding the currentbasic and clinical application progress of ESC, iPSC, RSC, MSC can provide a new idea for the treatment of retinal degeneration.