Objective To monitor the stem cell migration into the bone defect following an injection of the labeled mesenchymal stem cells (MSCs) by the enha nced green fluorescent protein (EGFP)technology and to provide insights into an application of MSCs for the fracture healing. Methods Isolated MSCs from the rabbit femur marrow were culture-expanded and were labeled by the transfection with the recombinant retrovirus containing the EGFP gene. Then, some labeled MSCs were cultured under the osteogenic differentiation condition and the phenotype was examined. After the fracture of their bilateral ulna, 18 rabbits were divide d into two groups. The labeled MSCs were injected into the aural vein at 1×107 cells/kg in the experimental group and the unmarked MSCs were injected in the control group 24 hours before surgery, and 1 and 24 hours after surgery, res pectively. Necropsies were performed 2 days after surgery in the two groups. The sections from the left defects were observed under the fluorescence microscope and the others were analyzed by the bright-field microscopy after the HE staining. Results The EGFP did not affect the MSCs viability. After the labeled cells were incubated in the osteogenic medium alkaline phosphatase, the calcium nodule s were observed. All the rabbits survived. The tissue of haematoma was observed in the bone defects and the fluorescent cells were found in the experimental gr oup, but no fluorescent cells existed in the control group. Conclusion The EG FP labeled MSCs can undergo osteogenic differentiation in vitro and can mig rate into bone defects after their being injected into the peripheral vein.
Objective To review the application advancements of ATP-binding cassette (ABC) transporter in medical research.Methods Relevant literatures about the applications of ABC families in medical research were reviewed. Results ABC families mainly took roles in transporting substances across cell membrane. Some of them were useful for the prediction of drug resistance and the prognosis of malignant tumors. Others were target s for molecular researches. Their expressions or mutations might be related with the occurrence of diseases. Conclusion ABC families are very important in the diagnosis and therapy for diseases. Thus they are very promising tools for future medical research.
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.
Objective To explore the in vitrodifferentiation of the rat mesenchymal stem cells (MSCs ) into the skeletal muscle cells induced by the myoblast differentiation factor (MyoD) and 5-azacytidine. Methods The MSCs were taken from the rat bone marrow and the suspension of MSCs was made and cultured in the homeothermia incubator which contained 5% CO2at 37℃. The cells were observed under the inverted phase contrast microscope daily. The cells spreading all the bottom of the culture bottle were defined as onepassage. The differentiation of the 3rd passage of MSCs was induced by the combination of 5-azacytidine, MyoD, transforming growth factor β1, and the insulin like growth factor 1. Nine days after the induction, the induced MSCs were collected, which were analyzed with the MTT chromatometry, theflow cytometry, and the immunohistochemistry. Results The primarily cultured MSCs grew as a colony on the walls of the culture bottle; after the culture for 5-7 days, the cells were shaped like the fibroblasts, the big flat polygonal cells, the medium sized polygonal cells, and the small triangle cells; after the culture for 12 days, the cells were found to be fused, spreadingall over the bottle bottom, but MSCs were unchanged too much in shape. After the induction by 5-azacytidine, some of the cells died, and the cells grew slowly. However, after the culture for 7 days, the cells grew remarkably, the cell volume increased gradually in a form of ellipse, fusiform or irregularity. After theculture for 14 days, the proliferated fusiform cells began to increase in a great amount. After the culture for 18-22 days, the myotubes increased in number and volume, with the nucleus increased in number, and the newly formed myotubes and the fusiform myoblst grew parallelly and separately. The immunohistochemistry for MSCs revealed that CD44 was positive in reaction, with the cytoplasm ina form of brown granules. And the nucleus had an obvious border,and CD34 was negative. The induced MSCs were found to be positive for desmin and specific myoglobulin of the skeletal muscle. The flow cytometry showed that most of the MSCs and the induced MSCs were in the stages of G0/G1,accounting for 79.4% and 62.9%,respectively; however, the cells in the stages of G2/S accounted for 20.6% and 36.1%. The growth curve was drawn based on MTT,which showed that MSCs weregreater in the growth speed than the induced MSCs. The two kinds of cells did not reach the platform stage,having a tendency to continuously proliferate.ConclusionIn vitro,the rat MSCs can be differentiated into the skeletal muscle cells with an induction by MyoD and 5-azacytidine, with a positive reaction for the desmin and the myoglobulin of the skeletal muscle. After the induction, the proliferation stage of MSCs can be increased, with a higher degree of the differentiation into the skeletal muscle.
Objective To establish a method of constructing skin-equivalents (SE) by the hair follicle stem cells (HFSC) and the fibroblasts. Methods The K19 immunostainning was employed to localize the HFSC in the human scalp from the cosmetic surgery. The isolated HFSC through the enzyme digestion were seeded on the dermal equivalent (DE) formed by polymerization of the fibroblasts and collagen. After being cultured between the air-liquid interface for 14 days, SE were harvested and used for an evaluation. Results HFSC were located mainly in the outer root sheath in the hair follicle. Based on DE, the growing HFSC could build a fullydeveloped and multilayered epidermis with the basal membrane formedb etween the epidermis and the dermis. The fibroblasts were active and spread evenly in the collagen matrix. Conclusion The hair follicle stem cells located in the outer root sheath can be successfully used to construct skin-equivalents in vitro and have a promising clinical use in the treatment.
ObjectiveTo review the recent research progress of skeletal myoblasts for cardiac repair. MethodsThe related literature about skeletal myoblasts for cardiac repair was reviewed, analyzed, and summarized. ResultsThe results of animal experiments and clinical studies have shown that skeletal myoblasts been transplanted into the regional myocardial infarction area in different ways can improve cardiac function. But there are some challenges such as high loss rate of skeletal myoblasts and resulting in ventricular arrhythmias. ConclusionFurther studies can improve the safety and effectiveness of skeletal myoblasts for cardiac repair in the future.
Objective To review recent advances in the application of hair transplantation in wound healing and scar repair in special areas. Methods An extensive review of the literature on the application of hair transplantation in wound healing and scar repair in special areas was conducted, focusing on cellular functions, molecular mechanisms, and clinical applications. ResultsHair transplantation has been shown to effectively promote wound healing and scar repair in special areas. The underlying mechanisms are complex, but current understanding emphasizes a strong association with hair follicle-associated stem cells (including epidermal stem cells, dermal papilla cells, dermal sheath cells, etc). ConclusionThe application of hair transplantation in wound healing and scar repair in special areas remains in its early stages. Further investigation into its mechanisms of action is essential, and randomized controlled trials are needed to establish its efficacy.
Age-related macular degeneration (AMD) is an age-related neurodegenerative eye disease characterized by degeneration and progressive death of retinal pigment epithelium (RPE) and photoreceptor cells. In recent years, as a new treatment for AMD, stem cell therapy has attracted wide attention in the field of AMD, and has become a current research hotspot. Although stem cell therapy carries risks such as increased incidence of cancer and immune rejection, it significantly promotes damaged photoreceptor cells and retinal cells by differentiating into RPE cells and other retinal cell types, as well as secreting neurotrophic factors and extracellular vesicles. In particular, the development of embryonic stem cell-derived RPE cells, its cryopreservation technology and the advancement of plasmid, adeno-associated virus, Sendai virus and other delivery technologies have laid a solid foundation for stem cell therapy of AMD. As a new method to prevent retinal damage and photoreceptor degeneration, stem cell neuroprotective therapy has shown great potential, and with the continuous maturity and improvement of these technologies, stem cell therapy is expected to provide new ideas for the prevention and treatment of AMD in the future.
Abstract: Objective To investigate the effects of haemopoietic stem cell mobilization on vein graft patency and intimal hyperplasia of anastomosis. Methods Twentyfour New Zealand rabbits were randomly divided into experimental group and control group, 12 rabbits in each group. A double side of carotid arteryvein transplantation model was made in each rabbit. One side of vein graft was digested by 0.25% trypsin for complete endothelial denudation before transplantation. Recombinant human granulocyte colonystimulating factor was given by subcutaneous injection 24 hours after operation, once per day in successive 10 days in experimental group, saline was given in the same way in control group. Bone marrow stem cells mobilization was observed after operation, including karyote counts and mononuclear cell proportion in peripheral blood. The patency rate of vein grafts and the degree of anastomosis intimal hyperplasia were observed too. Results The karyote counts (t=8.406,P=0.000)and mononuclear cell proportion(t=31.267,P=0.000) in peripheral blood of experimental group increased significantly 5 days after operation than those in control group. The vein grafts with intact endothelium had higher patency rate in both groups. In the vein grafts with complete endothelial denudation, the patency rate were obviously lower, but it was higher in experimental group than those in control group (67% vs. 30%). In the end of experiment, the pulsatility index of the vein grafts anastomosis with complete endothelial denudation was lower in experimental group than that in control group(t=2.958,P=0.009). Pathological examination showed that various degrees of intimal hyperplasia in all anastomoses of vein grafts were observed 4 weeks after operation. The degree of anastomosis intimal hyperplasia was more severe in vein grafts with complete endothelial denudation. Compared with control group, re-endothelization occurred completely in vein grafts with complete endothelial denudation of experimental group and the degree of anastomosis intimal hyperplasia was relatively lower (Plt;0.05). Conclusion Haemopoietic stem cell mobilization can provide protective effects on vein grafts by accelerating reendothelization which might increase vein grafts patency rate in the near future after operation and reduce anastomosis restenosis caused by intimal hyperplasia.