Objective To investigate the protective effect of nerve growth factor (NGF) on apoptosis of cultured human fetal retinal pigment epithelium (HFRPE) cells induced by indomethacin (IN) in vitro.Methods Subcultured HFRPE cells were treated with different concentrations of IN to establish apoptotic model. The protective effect of NGF on apoptosis of cultured HFRPE cells were assessed using an acridine orange (AO) staining method and transmission electron microscopy (TEM).Results HFRPE cells exposed by 200-600 μmol/L IN for 24 hours elicited typical apoptosis morphological changes, including condensed chromation, nuclear fragmentation and reduction of nuclear size and cell volume. There was a statistically difference in HFRPE cells with apoptosis between 200 μmol/L IN+500 μg/L NGF and 200 μmol/LIN groups ( q=3.9204,P=0.0320); there was a significant difference in HFRPE cells with apoptosis in 400 μmol/L IN+500 μg/L NGF and 400 μmol/ L IN as well (q=9.7915,P=0.0001). Conclusion NGF has an protective effect on IN-induced HFRPE cells apoptosis. (Chin J Ocul Fundus Dis,2003,19:38-41)
OBJECTIVE: To investigate the characteristic and phenotype of ectomesenchymal stem cells of human fetal facial processes and the procedure of spontaneous differentiation to smooth muscle cells. METHODS: The primary ectomesenchymal cells of E 50 human fetal facial processes were isolated by 2.5 g/L trypsin and cultured with DMEM/F 12 with 10(-6) U/L leukemia inhibitor factor(LIF). The morphology and growth rate were observed by inverted microscop. After being withdrawn LIF, the characteristic of cells were identified by immunohistochemistry and RT-PCR. Ultrastructure was observed by transmission electron microscope. RESULTS: The cultured cells displayed monolayer growth and were fibroblast-like with 2-4 processes. The cells were stainely positived for anti-human natural killer cell marker-1, Vimentin, S-100, neuron specific enolase, myoglobin and VIII factor, but negatively for glial fibrillary acidic protein, neural fiblament, alpha-SMA and cytokeratin in immunohistochemistry. Two days after being withdrawn the LIF, cells expressed alpha-SMA in protein and mRNA levels. The cells were rich in muscular filament-like structure and dense bodies under transmission electron microscope. CONCLUSION: Cultured cells are undifferentiated ectomesenchymal stem cells. The cells have the potential for differentiating spontaneously to smooth muscle cell.
Purpose To investigate the development of embryonic stem cells (ESC)in the subretinal space. Methods ESC were cultivated in suspension for 4 days till they developed into cell aggregates,i.e.embryonic body(EB).ESC as well as EB combined with or without RA were respectively transplanted into vitreous cavity and subretina1 space in SD rats,and the subretinal transplanted eyes,transient ischemia-reperfusion injuries were made by ligating the ophthalmic artery for 40 seconds before the transplantation .The experimental eyes were enucleated for histological and immunohistochemical assays after 14~28 d. Results The EB was found to develope into photoreceptors induced by RA in the subretinal space under an ischemia-reperfusion condition,and EB transplantation without RA induction induced multiple differentiations in the subretinal space.The single injection of RA without EB induced hyperplasia of the neural retinal cells.ESC transplanted into vitreous cavity rapidly proliferated and developed into atypical hyperplastic mass. Conclusion EB derived from ESC can differentiate into photoreceptors induced by RA in the host subretinal space under an ischemia-reperfusion condition. (Chin J Ocul Fundus Dis,2000,16:213-284)
Objective To investigate the possibility of ectomesenchymal stem cell of human embryo facial process in differentiating into osteoblasts.Methods Ectomesenchymal stem cells of human embryo facial process were isolated and cultured in mineralized promoting solution containing 10 mmol/L β-glycerophosphate, 100 μg/ml ascorbic acid and 10 nmol/L dexamethasone supplemented with 15% FBS. The morphological change was observed by phase contrast microscopy. The characteristics of cells was identified by immunohistochemistry assay. Alkaline phosphatase activity was tested and the form of mineralized nodules was tested with Von Kossa staining. The expression of osteocalcin was identified by RT-PCR.Results There were significant changes in the shape of the cells after 3 days cultured in mineralized promoting solution. The cells became larger and the shape changed from fibroblast-like to multilateral. The result for anticollogen typeⅠstaining was positive. The alkaline phosphatase activity increased. Mineralized nodules were formed aftercultured 25 days by Von Kossa staining. RT-PCR assay showed induced cells expressed osteocalcin.Conclusion Ectomesenchymal stem cells of humanembryo facial process can be induced to differentiate into osteoblasts by mineralized promoting solution.
Objective To review the latest development of the research on the selfrenwal signaling pathway and culture system in vitro of the embryonic stem cells(ESCs). Methods The recent articlesabout the selfrenewal signaling pathway and culture system in vitro of the ESCs were extensively reviewed. Results Understanding of the molecular mechanism of the selfrenewalin vitro and pluripotency of the ESCs was considered important for developing improved methods of deriving, culturing and differentiating these cells into the cells that could be successfully used in the clinical practice. Conclusion A further research is needed to elucidate the selfrenewal signaling pathway and the pluripotency of the ESCs and the culture systemin vitro forthe human ESCs remains to be further improved and developed.
Objective To explore an optional condition to induce mouse embryonic stem cell(ESC) to differentiate into endothelial cells so as to provide seedcells for tissue engineered vascular. Methods The embryos from one pregnant 12.5days mouse was harvested to culture the mouse embryonic fibroblasts(MEF). The ESC was reanimated by common method, and used to cultured into embryoid body(EB) in vitro. The EB which was used to induce into endothelial cells was divided into two groups. The EB was cultured in the EB medium with 3ng/ml transforming growth factor β1, 50 ng/ml vascular endothelial cell growth factor and 1 μmol/L potent and selective inhibitor of activin receptorlike kinase receptors in experimental group. The EB was cultured in the EB medium in the control group. After 14 days, RTPCR and immunohistochemistry were used to detect vWF and CD34, to analyze the morphology and type of the differentiated cells fromESC. Results The primary MEF had a high proliferation activity. At the 3rdday, the fusion rate of MEF was about 90% with a fusiform shape. The cells was fusiform shape and arranged compactly with fullness of nucleus and 2-3 entoblasts. The 3rd5th generations EB was polygonal with fullness of cytoplasm and 3-4 entoblasts. ESC could maintain undifferentiated state, and the cells unit lookedlike bird nest with smooth margin; the cells was small at size and b refractivity with high rate of nuclein and rapid proliferation. At 3 days of dropculture, EB can seen grossly and at 3 days of suspension, large and transparent EBformed. EB was spread radiately with an intensive adhesion at the 2nd day. In experimental group, many round cells was differentiated around EB from the 4thday to the 7th day, and form tubular structures from the 10th day to the 14th day. The vWF and CD34 were expressed. In control group, EB could not form tubularstructures, and the vWF and CD34 were not expressed. Conclusion ESC can differentiate into endothelial cells under some conditions, and form vessellike structure under condition culture, which can provide sources of seed cells for tissue engineered vessel.
Objective To establish a culture system in vitro of fetal and adult human retinal neural cells provide a model for the basic research of retinal neural cells and the medicinal exploitation. Methods Fetal human retinas(10~13 weeks after conception) and adult human retinas(20~40 years old) were dissected, dissociated, and put into culture plate which was coated with polylysine or rat tail gel. Specific growth factor EGF、FGF、BDNF or NT-4 were added to the culture medium. BrdU incorporation, Tunnel assessment and immuno-histochemistry and immuno-fluorescent staining were applied to determine cells proliferation, apoptosis and identify the component of cultured cells. Results Fetal human retinal cells and adult human retinal cells survived for up to 100 and 180 days in vitro. The addition of EGF、FGF、BDNF or NT-4 promoted the survival of both fetal and adult retinal neurons and stimultated proliferation of fetal retinal cells. The neurons or the rate of ganglion cells was observed with higher percentage in the group with growth factor adding than the group without. Conclusion Fetal and adult human retinal cells can be maintained in vitro and the fetal cells also can be expanded, which are helpful to generate retinal neurons for basic research and drug exploitation. The exogenous growth factors added to the culture medium can promote survival, proliferation and differentiation of retinal cells in culture. (Chin J Ocul Fundus Dis, 2002, 18: 279-282)
ObjectiveTo study the characteristics of the human umbilical cord perivascular cells (HUCPVC) isolated from human first trimester umbilical cord perivascular layer tissues and the differentiation into islet-like cell clusters in vitro. MethodsThe HUCPVC derived from human first trimester umbilical cord which was donated by the volunteers were isolated and subcultured. The surface markers such as stage-specific embryonic antigen 1 (SSEA-1), SSEA-3, SSEA-4, OCT-4, TRA-1-60, and TRA-1-81 were detected by immunohistochemical method. The first trimester HUCPVC were induced to embryoid bodies (EB)-like cell aggregations and islet-like cell clusters in vitro through a simple stepwise culture protocol (5 steps). The expressions of specific markers[α-fetoprotein (AFP), Nestin, and smooth muscle actin (SMA)] were measured by immunohistochemical method; and the ability of glucose-stimulated insulin secretion was analyzed. ResultsThe first trimester HUCPVC were successfully isolated and could be passaged steadily more than 10 generations, which expressed SSEA-3, SSEA-4, OCT-4, TRA-1-61, and TRA-1-81. The first trimester HUCPVC were successfully induced into EB-like cell aggregations and islet-like cell clusters. The EB-like cell aggregations could express markers of three germ lineages:AFP, Nestin, and SMA. The islet-like cell clusters could release insulin significantly in response to elevated concentrations of glucose in vitro (t=7.444, P=0.002). The insulin contents were (23.2±5.3) mU/L and (7.0±0.5) mU/L in high and low glucose media, respectively. ConclusionThe first trimester HUCPVC has the ability to differentiate into islet-like cell clusters which can secret insulin in vitro.
Diabetic retinopathy is a serious complication of diabetes and is the leading cause of blindness in people with diabetes. At present, there are many views on the pathogenesis of diabetic retinopathy, including the changes of retinal microenvironment caused by high glucose, the formation of advanced glycation end products, oxidative stress injury, inflammatory reaction and angiogenesis factor. These mechanisms produce a common pathway that leads to retinal degeneration and microvascular injury in the retina. In recent years, cell regeneration therapy plays an increasingly important role in the process of repairing diseases. Different types of stem cells have neurological and vascular protection for the retina, but the focus of the target is different. It has been reported that stem cells can regulate the retinal microenvironment and protect the retinal nerve cells by paracrine production, and can also reduce immune damage through potential immunoregulation, and can also differentiate into damaged cells by regenerative function. Combined with the above characteristics, stem cells show the potential for the repair of diabetic retinopathy, this stem cell-based regenerative therapy for clinical application provides a pre-based evident. However, in the process of stem cell transplantation, homogeneity of stem cells, cell delivery, effective homing and transplantation to damaged tissue is still a problem of cell therapy.