Objective To explore the feasibility of allogeneic marrow stromal stem cells(MSCs) as seed cells to construct tissue engineered bone bydetecting the expressions of interleukin 2(IL-2) and IL-2 receptor in rhesus monkeys after implanting these tissue engineered bones.Methods Engineered bones were constructed with osteoblasts which derived from allogeneic MSCs and bio-derived materials in vitro, and then were implanted to bridge 2.5 cm segmental bone defects of left radius in 15 rhesus monkeys as experimental group, bioderived materials only were implanted to bridge same size defects of right radius as control group. Every 3 monkeys were sacrificed in the 1st, the 2nd, the 3rd, the 6th andthe 12th weeks postoperatively and the expressions of IL-2 and IL-2 receptor in blood and graft samples were detected quantitatively by enzymelinked immuneosorbent assay (ELISA).Results There was no significant difference in the contents of IL-2 and its receptor between 2 groups(P>0.05). The contents ofIL-2 and its receptor increased from the 2nd week and maintained high level from the 2nd to the 6th week, but decreased after 6 weeks.ConclusionTissue engineered bones constructed with allogeneic MSCs and bio-derived materials show low immunogenicity. Allogeneic MSCs may be used as seed cells to construct tissue engineered bone.
Objective To explore the effect of the platelet-rich plasma (PRP) on proliferation and osteogenic differentiation of the bone marrow mesenchymal stem cells (MSCs) in China goat in vitro. Methods MSCs from the bone marrow of China goat were cultured. The third passage of MSCs were treated with PRP in the PRP group (the experimental group), but the cells were cultured with only the fetal calf serum (FCS) in the FCS group (the control group). The morphology and proliferation of the cells were observed by an inverted phase contrast microscope. The effect of PRP on proliferation of MSCs was examined by the MTT assay at 2,4,6 and 8 days. Furthermore, MSCs were cultured withdexamethasone(DEX)or PRP; alkaline phosphatase (ALP) and the calcium stainingwere used to evaluate the effect of DEX or PRP on osteogenic differatiation of MSCs at 18 days. The results from the PRP group were compared with those from the FCS group. Results The time for the MSCs confluence in the PRP group was earlier than that in the FCS group when observed under the inverted phase contrast microscope. The MTT assay showed that at 2, 4, 6 and 8 days the mean absorbance values were 0.252±0.026, 0.747±0.042, 1.173±0.067, and 1.242±0.056 in the PRP group, but 0.137±0.019, 0.436±0.052, 0.939±0.036, and 1.105±0.070 in the FCS group. The mean absorbance value was significantly higher in the PRP group than in the FCS group at each observation time (P<0.01). Compared with the FCS group, the positive-ALP cells and the calcium deposition were decreased in the PRP group; however, DEX could increase boththe number of the positiveALP cells and the calcium deposition. Conclusion The PRP can promote proliferation of the MSCs of China goats in vitro but inhibit osteogenic differentiation.
Objective To investigate the results of human amniotic membrane(HAM) which are loaded with marrow mesenchymal stem cells(MSCs) and epidermis cells in treating fullthickness skin defect combined with radiation injury. Methods Eight minipigs were used in this study. Three round fullthickness wounds(Ф3.67cm), which combined with radiation injury, were created on the dorsum of each side close to the vertebral column in each animal. Among 48 wounds, 24 left side wounds were treated with HAM loaded with MSCs and epidermis cells as experimental group (group A), 16 right side wounds with simple HAM (HAM group, group B) and 8 right side wounds with oil gauze as control (group C). The granulation tissue, reepithelization and wound area were observed after 1,2 and 3 weeks. Immunohistochemistry was performed using vWF as a marker for blood vessels.Image analysis was employed to test new area of wound at different interval time and healing rate of wound.Results The healing time of group A was 6 to 7 days faster than that of group C and 5 to 6 days faster than that of group B. After 15-17 days of graft, there were significant differences in new area of wound and healing rate between group A and groups B,C(Plt;001). New epidermis fully covered whole wound surface in group A, and their granulation tissue, which contained a lot of vWF, fibroblasts, capillaries and collagen, grew well. Many inflammatory cells still were seen in groups B and C, and their contents of vWF, fibroblasts, capillaries and collagen in granulation tissue were smaller than that in group A.Conclusion The graft of HAM loaded with MSCs and epidermis cells played an effective role in promoting healing of wound combined radiation injury with high quality.
Objective To explore a method to isolate, culture and multiplicate the placentaderived mesenchymal stem cells (PMSCs) and the bone marrow-derived mesenchymal stem cells (BMSCs) of rabbit,and to compare their biological characteristics. Methods PMSCs were isolated from placenta of 1fetation rabbitby Percoll density gradient centrifuge and cultured in vitro. BMSCs were isolated from hindlimb bone marrow blood of 1 new born rabbit by direct plates culturemethod. The 3rd passage PMSCs and BMSCs were observed by inverted phase contrast microscope. The stem cell marker (CD44, CD105, CD34 and CD40L) were examined by immunohistochemistry. The 2nd passage PMSCs and BMSCs were co-cultured with biomaterials,(1.0-1.5)×106 cells in one biomaterial, and then observed by aematoxylinstaining after 5 days,and by SEM after 3 days and 8 days. Results PMSCs and BMSCs were both uniformly spondle-shaped in appearance and showed active proliferative capacity. The proliferative ability of PMSCs were quite b and declined with passages. After cultured 10 passages in vitro, its growthslowed. Both PMSCs and BMSCs expressed CD44 and CD105,but did not express CD34 and CD40L immunoreactivity. PMSCs and BMSCs poliferated and adhered to the surface of biomaterials, and cell formed clumps and network; the cells proliferation and the matrix were seen in the pore after 5 days of culture. The observation ofSEM showed that many cells adhered to the biomaterials with spindle-shape and polygon after 3 days; and that PMSCs and BMSCs grew,arranged in layers andsecreted many matrices; the reticular collagen formed arround cells after 8 days. Conclusion PMSCs and BMSCs have similar biological characteristics and PMSCs can be served as excellent seedingcells for tissue engineering.
Objective To study the effect of transforming growth factor β1(TGF-β1) and insulin-like growth factor 1(IGF-1) during the induction course from marrow mesenchymal stem cells (MSCs) to chondrocytes and to observe the effect of cell density on cell induction. Methods Differential time adherent methods were used to purify MSCs obtained from the bone marrow of Kunming mice. MSCs were cultured under special conditionsto induce themto differentiate into chondrocytes. Toluidine blue staining and immunofluoresence were used to identify those induced chondrocytes.TGF-β1 and IGF-1 were used individually or in combination under two different culture patterns: pellet culture and monolayer culture. According to different growth factors, experiment included 3 experimental groups(TGF-β1+IGF-1 group,10 ng/mland 50 ng/ml respectively;TGF-β1 group, 10 ng/ml; and IGF-1 group, 50 ng/ml) and control group(without growth factor). In TGF-β1+IGF-1 group, toluidine blue staining and immunofluoresence staining were carried out at 14 days and 21 days. The effect ofTGF-β1 and IGF-1 on the expression of collagen Ⅱgene was detected by RT-PCR at 7, 14 and 21 days of induction; the expressionsof collagen Ⅱ were compared between two culture patterns. Results In TGF-β1+IGF-1 group, the histological examination and immunofluoresence showed that those inducted chondyocytes could express collagen Ⅱ at 14 days. The gel electrophoresis results showed that the fragment of collagen Ⅱ gene was seen in TGF-β1+IGF-1 group andTGF-β1 group and that no fragment ofcollagen Ⅱ gene was seen in IGF-1 group and control group. The expression of collagen Ⅱ gene was ber in TGF-β1+ IGF-1 group than inTGF-β1 group, showing significant difference(Plt;0.05). Cells expressed more collagen Ⅱ under pellet culture than under monolayer culture. Conclusion IGF-1 could enhance the effect ofTGF-β1 during the induction course from MSCs to chondrocytes. A certain extent of high cell density is more effective for MSCs to differentiate into chondrocytes.
Objective To investigate the impact of bone marrow mesenchymal stem cell transplantation on a rat model of experimental autoimmune uveitis (EAU) and analyze its immune regulatory mechanisms in vivo.Methods Eighteen Lewis rats were randomly divided into three groups: model control group, intervention group and normal control group, six animals in each group. Human retinal S-antigen peptide (HS-AgP35, 1 mg/ml) was mixed and emulsified with complete Freundprime;s adjuvant and injected into hind foot pad of rats on the first and eighth day to establish the animal model of EAU. For bone marrow mesenchymal stem cell transplantation, 1 ml of cell suspension (2times;106 cells/ml) was injected into tail vein of the intervention group rats on the first day when the emulsified S-antigen was injected. EAU manifestation, pathological change and IFN-gamma; level were evaluated and compared among those three groups after two weeks. Results No abnormal signs were found in the eyes of rats in normal control group. The manifestation grading of the intervention group (two rats at grade 0, three rats at grade 0.5, one rat at grade one) was significantly different from the model control group (one rat at grade one, one rat at grade two, three rats at grade three, one rat at grade four) (P=0.015). The retina of rats in normal control group was ordinary under light microscope. The histopathologrical grading of the intervention group (one rat at grade 0, four rats at grade 0.5,one rat at grade one) and the model control group (four rats at grade three, two rats at grade four) was also statistically different (P<0.01). Furthermore, the IFN-gamma; level in peripheral blood of the intervention group rats declined significantly compared to the model control group (t=9.0574, P=0.01). Conclusions Bone marrow mesenchymal stem cells can inhibit EAU significantly, possibly by lowering the level of IFN-gamma;, thereby reduce the severity of uveitis and improve the condition of uveitis in rats.
OBJECTIVE To investigate the effect of percutaneous bone marrow graft for the management of nonunion of tibia. METHODS From March 1996 to June 2000, 56 cases with nonunion of tibia were treated by autogenous bone marrow graft. Among them, there were 38 males and 18 females, aged from 19 to 72 years. A marrow needle was inserted into the site of the nonunion under the X-ray, the autogenous bone marrow was injected into the site of nonunion. Compression bandage and appropriate immobilization material were applied after operation. This procedure was repeated every month, 2 or 3 times was needed. RESULTS 56 patients were followed-up for 4 months to 4 years and 2 months, averaged 2.8 years. Fracture healed in 53 cases and X-ray displayed fracture line disappeared and a great deal of continuous callus formed, and nonunion in 3 cases. CONCLUSION Percutaneous autogenous bone marrow graft can play a role in osteogenesis at the site of nonunion. It is easy to aspirate bone marrow and the operation is simple. It has clinical application value for the satisfactory effect.
Objective To investigate the effect of astragalus polysaccharides(AP) on chitosan/polylactic acid(AP/C/PLA)scaffolds and marrow stromal cells(MSCs)tissue engineering on periodontal regeneration of horizontal alveolar bone defects in dogs. Methods MSCs were isolatedfrom the bone marrow and then cultured in conditioned medium to be induced to become osteogenic.The MSCs were harvested and implanted into AP/C/PLA and C/PLA scaffolds.A horizontal alveolar bone defect(5 mm depth, 2 mm width)were produced surgically in the buccal side of the mandibular premolar 3 and 4 of 10 dogs.The defects were randomly divided into 4 groups(n=10):Group A, root planning only(blank contro1); group B, AP/C/PLA with conditioned medium(medium contro1);group C, C/PLA with MSCs(scaffolds contro1); and group D, AP/C/PLA with MSCs(experimental group).Eight weeks after surgery, block sections of the defects were collected for gross, histological and X-ray analysis. Results MSCs induced in vitro exhibited an osteogenic phenotype with expressingcollagen I and alkaline phosphatase. X-ray film observation showed that the bone density and height had no changes in group A; in group B, the bone density was increased to a certain extent and furcation area reached a few height, but no height was increased in interdental septum; in group C,the bone density was increased and furcation area nearly reached the native height,but interdental septum reached a few height;in group D,the bone density was increased significantly and furcation area and interdental septum reached the native height. Histological evaluation showed that there was greater tissue formation in group D than that in groups A, B and C, in which new alveolar bone, new cementum, periodontal ligament with Sharpey’s fibers, and new bone tissue was similar to native periodontal tissues. Ingroup A,B, C and D respectively, the amount of new alveolar bone regeneration was 0.83±0.30, 1.46±0.55, 2.67±0.26 and 2.90±0.41 mm; new cementum regeneration was 0.78±0.45,1.30±0.60,2.29±0.18 and 2.57±0.22 mm; the amount of connective tissue adhesion was 0.80±0.22,1.33±0.34,2.23±0.42 and 2.64±0.27 mm; all showing significant differenecs between group D and groups A, Band C (Plt;0.05).Conclusion The technology of tissue engineering with AP/C/PLAscaffolds and induced MSCs may contribute to periodontal regeneration.
Abstract: Objective To construct a nesprin-siRNA lentiviral vector(LV-siNesprin), transfect it into bone marrow mesenchymal stem cells (MSCs), and observe morphology changes of MSCs. Methods According to the target gene sequence of nesprin, we designed and synthesized four pairs of miRNA oligo, which were then annealed into double-strand DNA and identified by sequencing. MiRNA interference with the four kinds of plasmids (SR-1,SR-2,SR-3, andSR-4) were transfected into rat vascular smooth muscle cells, and reverse transcriptase chain reaction(RT-PCR) and Western blotting were performed to detect the interference effects and filter out the most effective interference sequence. We used the best interference sequence carriers and pDONR221 to react together to get the entry vectors with interference sequence. Then the objective carrier pLenti6/V5-DEST expressing both entry vectors and lentiviral vectors was restructured to get lentiviral expression vector containing interference sequence (LV-siNesprin+green fluoresent protein (GFP)), which was packaged and the virus titer was determined. LV-siNesprin+GFP was transfected to MSCs, and the expression of nesprin protein(LV-siNesprin+GFP group,GFP control group and normal cell group)was detected by Western blotting. The morphology of MSCs nuclear was observed by 4’,6-diamidino-2-phenylindole (DAPI) stain. The proliferation of MSCs (LV-siNesprin+GFP group,GFP control group and normal group) was detected by 3-(4,5-dimethylthia- zol-2-yl)-2,5-diphenyltetrazolium bromide(MTT) after lentivirus transfected to MSCs at 24, 48, 72, and 96 hours. Results The four pairs of miRNA oligo were confirmed by sequencing. Successful construction of LV-siNesprin was confirmed by sequencing. The best interference with miRNA plasmid selected by RT-PCR and Western blotting was SR-3. Lentiviral was packaged, and the activity of the virus titer of the concentrated suspension was 1×106 ifu/ml. After MSCs were transfected with LV-siNesprin, nesprin protein expression significantly decreased, and the nuclear morphology also changed including fusion and fragmentation. The proliferation rate of MSCs in the LV-siNesprin+GFP group was significantly slower than that of the GFP control and normal cell groups by MTT. Conclusion Nesprin protein plays an important role in stabilizing MSCs nuclear membrane, maintaining spatial structure of MSCs nuclear membrane,and facilitating MSCs proliferation.