ObjectiveTo review the advances in utilizing paracrine effect of stem cells in knee osteoarthritis (OA) treatment.MethodsThe researches in applying stem cells derived conditioned medium, extracellular matrix, exosomes, and microvesicles in knee OA treatment and cartilage repair were reviewed and analyzed.ResultsThe satisfying outcomes of using different products of stem cells paracrine effect in knee OA condition as well as cartilage defect is revealed in studies in vitro and in vivo. The mechanism including suppressing the intraarticular inflammation, the apoptosis of chondrocytes, and the degradation of cartilage matrix, while enhancing the synthesis of cartilage matrix, the differentiation of in-situ stem cells into chondrocytes and the migration to the affected area. The effectiveness can be further improved supplemented with the tissue engineering methods or gene modification.ConclusionCompared with the traditional stem cell therapy, applying the products from paracrine effect of stem cells in knee OA treatment is more economical and safer, presenting great potential in clinical practice.
Retinitis pigmentosa (RP) is a genetic disorder of photoreceptor cell apoptosis and retinal pigment epithelium (RPE) cell atrophy caused by gene mutation. The clinical manifestations are night blindness, peripheral visual field loss and progressive vision loss. RPE cell apoptosis plays an important role in the progression of RP, and exogenous implantation of RPE cells as an alternative therapy has shown certain efficacy in animal experiments and clinical trials. With the diversification of cell sources, the update of surgical techniques and the continuous emergence of biological materials, more possibilities and hopes are provided for cell therapy. To further promote the development of this field in the future, it is still necessary to strengthen the cooperation between medicine, bioengineering and other disciplines in the future to jointly promote the innovation and development of therapeutic methods. It is believed that RPE cell transplantation therapy will show a brighter prospect in the future
Objective To review and summarize the latest development of the therapy for the Duchenne muscular dystrophy (DMD). Methods Therecentlypublished articles related to the therapies for DMD were extensively reviewed and briefly summarized. Results The therapeutic approaches for DMD included the gene therapy, the cell therapy, and the pharmacological therapy. The gene therapy and the cell therapy were focused on the treatment for the cause of DMD by the delivery of the missing gene, the modification of the mutated gene, and the transfer of the normal cells including the stem cells, while the pharmacological therapy dealt with the downstream events caused by the dystrophin gene defect, slowed down the pathologic progress of DMD, and improved the DMD patient’s life quality and life span, by medication and other factor treatments. Conclusion There is still no cure for DMD because of various difficulties in replacing or repairing thedefected gene and of the multifaceted nature of the severe symptoms. Therefore,it is imperative for us to find out a more effective treatment that can solve these problems.
ObjectiveTo study the external biocompatibility bewteen the mouse induced pluripotent stem cells (miPSCs) and poly-3-hydroxybutyrate-co-3-hydroxyhexanoate (PHBHHx). MethodsAfter we recovered and subcultured miPSCs, we divided them into two groups. There was one group cultured with material of PHBHHx films outside the body. We observed the adhesive pattern of miPSCs on film by fluorescence of 4, 6-diamidino-2-phenylindole (DAPI) staining. The cell vitality was detected by cell counting kit-8 (CCK-8). The morphology of miPSCs attached on the film was visualized under scanning electron microscope (SEM). We used the traditional petri dish to culture miPSCs and detect the cell activity by CCK-8. ResultsMiPSCs can adhere and proliferate on PHBHHx films. The result of cell vitality which detected by CCK-8 showed that there was a statistical difference in OD value between culturing on PHBHHx films and traditional cultivation (0.617±0.019 vs. 0.312±0.004, P < 0.05). ConclusionThere are adhesion and proliferation on the surface of cells patch made by miPSCs co-culturing with PHBHHx film. Compared with traditional culturing in the cell culture dish, culturing in PHBHHx films have great advantages in the process of adhesion and proliferation. PHBHHx can be used as one of the scaffold for stem cells treating various disease.
Abstract: Objective To transplant the microencapsulated recombinanted Chinese hamster ovary (CHO ) cells into the infracted myocardium of rodent animals and investigate whether vascular endothelial growth factor (VEGF) secreted by the implanted CHO cells could augment angiogenesis and improve cardiac function. Methods The cDNA of VEGF was transferred into CHO cells with plasmid stable transfection. After microencapsulation, the cell growth in microcapsules and the VEGF level in the culture supernatant were evaluated. Two weeks after myocardial infarction, the microencapsulated CHO cells (MC-CHO group ) were implanted into the border of infracted myocardium, as well as similar amount of CHO cells (CHO group ) , blank microcapsule (MC group ) and non-serum culture medium (control group ) as controls, 12 rats per group. The cardiac function improvement was evaluated 3 weeks after transplantation, while the survival status of implanted CHO cells, in situ secretion of VEGF and capillary density were assayed by histology. Results CHO cells could grow and proliferate after microencapsulation. The secretion of VEGF was detectable in culture media supernatant, with the highest concentration of 3 852 pg/m l at day 8. As compared to the other three groups, the left ventricular dimension and cardiac function were significantly improved in MC-CHO group 3 weeks after transplantation. The capillary density of MC-CHO group were increased significantly than those of CHO group, MC group and control group (22. 3±3. 1 vs. 15. 6±2. 8, 11. 4±2. 5, 13. 2±2. 7 vessels per 0.13 mm2, P lt; 0.05). The implanted microcapsule maintained its original shape and protected theCHO cells in it. Conclusion M icroencapsulaed recombinanted CHO cells transplantation might be a promising app roach to augment angiogenesis and improve the cardiac function in infarction myocardium.
Objective To investigate the effects of chondroitinase ABC (ChABC) combined with bone marrow mesenchymal stem cells (BMSCs) in repair spinal cord injury of rats. Methods Primary BMSCs were isolated and cultured from the femur and tibia of neonatal Sprague Dawley (SD) rats. The spinal cord injury model was established in 24 adult SD male rats (weighing, 200-230 g), which were randomly divided into control group (group A), BMSCs transplantation group (group B), ChABC injection group (group C), and ChABC and BMSCs transplantation group (group D), 6 rats in each group. At 7 and 14 days after injury, Basso-Beattie-Bresnahan (BBB) score criteria was used to evaluate the hindlimb motor function; at 14 days after injury, the injured spinal cord tissue was perfused and stained by HE for further calculation of the injury area. Immunofluorescence staining were used for observing the expressions of glial fibrillary acidic protein (GFAP)/chondroitin sulfate proteoglycan (CSPG) and GFAP/growth associated protein 43 (GAP43). Results At 7 days after injury, three joints movement of the hindlimbs were recovered in all groups, and no significant difference in the BBB score was found among 4 groups (P gt; 0.05). At 14 days after injury, no load drag was observed in 3 joints of the hindlimbs in groups A, B, and C, but weight-bearing plantar or occasional dorsalis pedis weight-bearing walking was observed in group D with no plantar walking. The BBB score of group D was significantly higher than that of the other 3 groups (P lt; 0.05). HE staining showed that the cavity formed in the damage zone, and there were a large number of macrophages in the cavity and its surrounding, which was wrapped by scar tissue. The damage area of group D was significantly smaller than that of the other 3 groups (P lt; 0.05). At 14 days after injury, the GFAP/CSPG double immunofluorescence staining showed that the astroglial scar damage zone in group D was significantly reduced, and no cavity formation was found. And the fluorescence intensity in groups C and D was significantly lower than that in group B (P lt; 0.05). The GFAP/GAP43 double immunofluorescence staining showed that GAP43-positive fibers passed through the damage zone in group D and the fluorescence intensity in group D was significantly higher than those in groups B and C (P lt; 0.05). Conclusion Inhibition of astrocytes secreting CSPG by ChABC combined with BMSCs transplantation in early injury may promote the regeneration of nerve fibers, and repair spinal cord injury in rats.
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.
【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 study whether human amniotic fluid colony derived stem cells (hAFCSCs) are involved in regeneration of injured muscles in mice and to investigate the method and feasibil ity of hAFCSCs-based cytotherapy in the treatment of injured muscles. Methods Human second-trimester amniotic fluid was collected through ultrasound-guided amniocentesis, hAFCSCs were isolated from second-trimester amniotic fluid and cultured, and the cells at 6th-8th passages were spared. The mRNA was extracted to identify the stem cell related genes by RT-PCR. The muscular injury model of bilateral tibial is anterior muscle was establ ished by cardiotoxin and X-ray irradiation in 16 Nod/Scid mice (aged 6-8 weeks, and weighing 20-24 g). The hAFCSCs (3.3 × 107/mL, 30 μL) were injected into the right injured tibial is anterior muscles as the experimental group, while the same volume of complete medium (α-MEM containing 15%FBS, 18%Chang B, 2%Chang C, 1% penicill instreptomycin, and 1% L-glutamine) was injected into the left injured tibial is anterior muscles as the control group. At 2 and 4 weeks after cell transplantation, the immunofluorescence staining of tibial is anterior muscles was performed to detect hepatocyte growth factor receptor (c-Met), myogenic regulatory factor (Myf-5), Laminin, Desmin, and human specific nuclear mitotic apparatus protein (NuMa). Results The clone formation was observed at 5-7 days of primary hAFCSCs culture; after 8-10 days, the clones with homogeneous morphology were selected for subculture. Adequate stem cells were available after 6th-8th subculture. RT-PCR analysis showed that hAFCSCs expressed mRNA of the stem cell related genes. The immunofluorescence double-staining showed that NuMa expressed in tibial is anterior muscles of the experimental group and no myogenic phenotype expressed at 2 weeks after cell transplantation, and that single cell co-expressed NuMa and c-Met or Myf-5 at 4 weeks after cell transplantation. In some myofibers, NuMa and Laminin or Desmin were also co-expressed. No NuMa positive hAFCSCs were detected in the control group at 2 and 4 weeks after cell transplantation. Conclusion hAFCSCs can participate in the regeneration of injured mouse muscle.