Objective To test the hypothesis that marrow stromal cells (MSCs), when implanted into selfmyocardium in rabbits, can undergo milieu-dependent differentiation and express cardiomyogenic phenotypes and enhance cardiac function of ischemic hearts, through establish a clinically relevant model for autologous MSCs transplantation, Methods Thirteen New Zealand White rabbits were randomly divided into experimental group (n= 7) and control group (n= 6). In experimental group, autotogous MSCs(3× 106 cells/30μl) labeled with Bromodeoxyuridine (BrdU) were respectively injected into superior, central and inferior sites in the periphery of the myocardial infarct region. Phosphate buffer saline (PBS) was injected into the scar of the control group hearts according to the same procedure used in the experimental group. Four weeks later, the transplanted labeled MSCs were detected by laser scanning confocal microscopy and the cardiac function were examined by echocardiogram and muhichannel physiologic recorder. Results After 4 weeks, transplanted MSCs were demonstrated myogenic differentiation with the expression of α-sarcomeric actin and connexin 43 located in intercalated disk. MSCs increased the number of vessels compared with controls in myocardial ischemia area. MSCs implantation resulted in markedly improved left ventricular contractility[left ventricular ejection fraction (LVEF): 0. 51 ± 0.07 vs. 0. 43 ± 0.06 ,left ventricular lateral wall motion distance (LVLWMD) :1. 75±0. 42mm vs. 1.09±0. 28mm, left ventricular systolic wall thickening ratio(LVAT) :0. 19%±0.05% vs. 0. 11%±0.04%, left ventricular systolic pressure (LVSP): 113. 1± 6.3mmHg vs. 99, 5 ± 5, lmmHg, left ventricular end diastolic pressure (LVEDP): 11. 5±2. lmmHg vs, 14, 3 ±3. lmmHg, maximum rate of left ventricular pressure rise (+dp/dtmax):4 618. 3±365. 2 mmHg/s vs. 3 268. 1± 436.9 mmHg/s, maximum rate of left ventricular pressure fall (-dp/dtmax) :3 008.8±346.7 mmHg/s vs. 2 536.9± 380.4 mmHg/s, P〈0.05]. Conclusion Transplanted autologous MSCs are able to undergo differentiation to form myocardial cells and improve the cardiac function of ischemia myocardium effectively. Autologous MSCs transplantation may have significant clinical potential in treatment myocardial ischemia.
Objective To investigate the effect of the injectable osteoinductive material with fibrin sealant(FS) as a carrier compounded with bone morphogenetic protein (BMP) on the proliferation and differentiation of marrow stromal cells (MSCs) towards osteoblasts and to provide the experimental foundation for the clinical application. Methods MSCs were extracted and cultured from bone marrow of the 3-day-old rabbit, and the third generation culturedMSCs were studied. The experiment included the experimental group(FS,including 1 μg/ml rhBMP-2), FS control group(FS)and blank control group (no material).The proliferation rate, the adhesive rate, the expression of the collagen Ⅰ and alkaline phosphatase, cell growth condition in the material and the ultrastructure of MSCs were investigated by electron microscopy, histochemistry and cell culture. Results The proliferation rate and the adhesive rate of MSCs in experimental group was significantly higher than those in blank control group ,but lower than those in FS control group (P<0.05). The expression level of thecollagen Ⅰ and alkaline phosphatase in the experimental group was significantlyhigher than those in all control groups(Marrow stromal cells Fibrin sealant Bone morphogenetic protein Cell culture Rabbits0.05). Scanning electron microscope showed that the surface of material was rough and had many pores and that celland material mixed. Transmission electron microscope showed that MSCs of the experimental group were mostly of the phenotype of osteoblasts with relatively lowproliferation activity and high differentiation degree toward osteoblasts and with plenty of extracellular matrix and collagen fibers. MSCs of FS control group had low differentiation degree toward osteoblasts with few extracellular matrix and collagen fibers and high proliferation activity. MSCs of blank control group had low differentiation degree toward osteoblasts with few extracellularmatrix and collagen fibers, and low proliferation activity. Conclusion The injectable osteoinductive material with fibrin sealant as a carrier compounded with BMP could significantly accelerate the differentiation of MSCs towards osteoblasts. But it could not significantly accelerate the proliferation activity of MSCs.
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.
Objective To observe the heterotopic osteogenes is of the autogenou s marrow stromal cells (MSCs) on the ceramic bovine bone(CBB)/hydrogel scaffold (HG) and t he effects of the recombinant human bone morphogenetic protein2 (rhBMP-2) and the transforming growth factor β (TGF-β) on osteogenesis. Methods The auto genous marrow stromal cells were cultured by the mineralized condition medium (1 0%FBS, dexamethasone 10 nmol, L-vitamin C 50 mg/L, βsodium glycerophosph ate D MEM culture medium 10 mmol). At 5 days, the MSCs differentiation was observed b y TypeⅠcollagen, the Mend calcium-cobalt staining, and the Von-Kossa staining. The cell suspension of 5×106/ml was obtained. There were three groups: Group A: added in rhBMP-2(10 μg)TGF-β(0.05 μg);Group B: added in TGF-β(0.05 μg); and Group C (the control group): without the growth factor. Then, the MSCs loading on CBB/HG were embedded in the autogenous subcutaneous area at 4 and 8 weeks, and the osteogenesis was observed by the HE staining and the modified Mallory’s trichrome staining, with an image analysis. TypeⅠcollagen and the bone m orphogenetic synthesis were examined by the immunohistochemistry stains. Results Most MSCs induced by the mineralized condition medium at 5 da ys became smalle r and polygon-shaped, and the cytodendrite became shorter. The MSCs were observ e d by the Mend calciumcobalt staining. Some brown and black grains were found in the cytochylema. The MSCs were positive for the TypeⅠcollagen immunohistochemi stry stains. At 20 days, the mineralized nubs were found by the Von Kossas stain s. At 4 weeks, some strips of the new bone were observed by the HE staining an d the modified Mallory’s trichrome staining in all the groups. The bone matrix a rea was significantly larger in Group A than in Group B(P<0.01). The av erag e gray degrees of TypeⅠcollagen were lower in Groups A and B than in Group C. However, there was no significant difference in the bone morphogenesis among the three groups. At 8 weeks, there- were significantly more snatchy strips and macula mature bone formation in Groups A and B than in Group C. The Type Ⅰcollage n and the bone morphogenesis were not significantly different among the three groups. Conclusion The autogenous marrow stromal cells on the ce ramic bovine bon e /hydrogel scaffold can promote the heterotopic osteogenesis, and the combined use of rhBMP-2 and TGF-β is better than the only use of rhBMP-2 or TGF-β i n promoting osteogenesis.
Objective To review researches on the relation between marrow stromal cells(MSCs) and repair of bone defect. Methods The latest original literatures about marrow stromal cells and their use in the treatment of bone defect were extensively reviewed. Results Marrow stromal cells were induced to osteoblasts under proper conditions and showed the potential of bone formation in vivo. The methods of bone tissue engineering using MSCs as seed cells and gene therapy using MSCs as target cells were bothuseful in the repair of bone defect.Conclusion MSCs have a promising future in the repair of bone defect.
Objective To review the advances in gene expression of marrow stromal cells(MSCs) in biological characteristic, differentiation, gene therapy, supporting hematopoiesis, inflammation reaction in wound repair.Methods The related articles in recent years were extensively reviewed.Results MSCs can express not only specific mRNA of mesodermal cells but also that of endodermal and ectodermal cell types on various differentiation conditions. When transfected or transducted, MSCs can steadily express many therapeutic transgenesin vitro or in vivo as well. Furthermore, they have the ability to support hematopoietic system and participate in the process of inflammation in wound repair.Conclusion MSCs are stem cells which have the characteristicof self renewing, multipotency and easy to expand in vitro. MSCs are ideal target cells for cell and gene therapies.
Objective To observe the ability to repair bilateralradius bone defect with the composite of β-tricalciumphosphate(βTCP),hyaluronic acid(HA),type I collagen(COL-Ⅰ) and induced marrow stromal cells(MSCs), and to investigate the feasibility of the composite as a bone substitute material.Methods The MSCs of the New Zealand white rabbits were induced into ostoblasts, then combined with β-TCP, HA and COL-Ⅰ. Thirty New Zealand white rabbits were made the bilateral radius bone defects of 2 cm and divided into groups A, B and C. After 8 weeks, β-TCP-HA-COL-Ⅰ-MSCs (group A, n=27 sides), autograft (group B, n=27 sides)andno implant(group C as control, n=6 sides)were implanted into the areas ofbilateral radius bone defects, respectively. The structure of the composite was observed by scanning electron microscope. The repairing effect was observed by gross, histomorphology, X-ray examination, and the degradation rate of inorganic substance at 4, 8 and 12 weeks. The ostogenic area and biomechanics ofgroup A were compared with those of group B at 12 weeks.Results The MSCs could stably grow in vitro, relatively rapidly proliferated, and could be induced into the ostoblasts.The composite was porous. The results of gross, histomorphology and X-ray showed that the bone defects were perfectly repaired in group A and group B, but not in group C. The ostogenic area or biomechanics had no statistically significant difference between groups A and B(Pgt;0.05). The weight of inorganic substance in group A were 75% ,57% and 42% at 4,8,12 weeks, respectively.Conclusion MSCs can be used as seedcells in the bone tissue engineering. The composite has porous structure, no reactions of toxicity to the tissue and rapid degradation, and it is an ideal carrier of seed cells.The β-TCP-HA-COL-Ⅰ-MSCs composite has the high ability of repairing bone defect and can serve as an autograft substitute material.
OBJECTIVE: To investigate the effect of compound pattern of ceramic bovine bone (CBB) and hydrogel(HG) on attachment, proliferation and differentiation of bone marrow stromal cell (MSC), and to find out the best way of constructing tissue engineered bone. METHODS: CBB, HG and MSC was compounded in different patterns and sequences to form CBB/HG/MSC (group A), HG/MSC/CBB (group B), CBB/MSC/HA (group C) and CBB/MSC (control group). Attachment and morphology of MSC were observed by scanning electronic microscope; the proliferation of MSC was evaluated by cell count; alkaline phosphatase(ALP) activity was examined by histochemistry and type I collagen synthesis was examined by immunohistochemistry staining 5 and 10 days later. RESULTS: In group A, MSC spread better, and ALP activity of group A was significantly higher than that of group B and control group(P lt; 0.01); but there was no significant difference between group A and group C(P gt; 0.05). There was no significant difference in type I collagen synthesis between four groups on the 5th day; but mean gray scale of type I collagen in group B was significantly higher than that in the other groups on the 10th day(P lt; 0.01). CONCLUSION: Different compound patterns of CBB, HG and MSC affect attachment, proliferation, differentiation of MSC. The compound pattern of CBB/HG/MSC is better than the others.