Objective To observe the impact of collagen patches using 1-ethyl-3- (3-dimethylaminopropyl) carbod-iimide hydrochloride chemistry (EDC) to conjugate vascular endothelial growth factor (VEGF) + basic fibroblast growth factor (bFGF) or VEGF alone on the survival rate of transplanted human bone morrow mesenchymal stem cells (hBM-MSCs)in vitro and in vivo. Methods Collagen patches which were activated by EDC were used as the control group,and EDC activated collagen patches that were conjugated with VEGF or VEGF + bFGF were used as the experiment groups(VEGF group and VEGF + bFGF group). hBM-MSCs (0.5×106/patch) were used as seeding cells to construct engineered heart tissue (EHT). MTT assay was performed to assess in vitro proliferation of hBM-MSCs on 3 different collagen patches. Ventricular aneurysm model after myocardial infarction was created by left anterior descending artery (LAD) ligation in male SD rats,and EHT which were constructed with 3 different patches were used for ventricular plasty. Four weeks later,immunofluorescence staining was used to examine arteriole density (anti-α-SMA staining) and transplanted cell survival (anti-h-mitochondria staining). Results (1) hMSCs proliferation in VEGF group and VEGF + bFGF group was significantly better than that in the control group on the 2nd and 4th day after cell transplantation (P<0.05); (2) Four weeks afterEHT implantation,immunofluorescence staining for α-SMA revealed that arteriole density of VEGF group and VEGF + bFGF group was significantly higher than that of the control group (P<0.05); (3) Immunofluorescence staining forh-mitochondria showed that survival rates of transplanted hBM-MSCs of VEGF group and VEGF + bFGF group were significantly higher than that of the control group (P<0.05); (4) There was a significantly positive correlation between survival rate of hBM-MSCs and arteriole density (r 2=0.99,P=0.02). Conclusion VEGF or VEGF + bFGF conjugated collagen patch can significantly improve hBM-MSCs proliferation in vitro and enhance survival rate of transplanted hBM-MSCs by accelerating revascularization of EHT in vivo.
Decellularized tissue engineering scaffolds appear to have the properties of similar structure and mechanical characteristics to native tissues,good biocompatibility,suitability for cell adhesion,growth and angiogenesis induction,and non-immunogenicity. Genipin has anti-inflammatory,antithrombotic and antioxidative features which can considerably suppress vascular and endothelial inflammatory activation,increase mechanical strength of biological scaffolds,inhibit inflammatory response and decrease degradation rate of biological scaffolds. By cross-linking with decellularized matrices,Genipin can further improve corresponding performance of tissue engineering matrices,which is very helpful to promote the application of tissue engineering into clinical practice of cardiothoracic surgery. This review focuses on recent research process and possible prospects of Genipin cross-linking in tissue engineering in the field of cardiothoracic surgery.
The establishing of myocardial tissue engineering techniques not only solve a series of issues that generate in cell and tissue transplantation after myocardial infarction, but also create a platform for selecting better materials and transplantation techniques. However, both experimental animal studies and recent clinical trials indicate that current transplantation techniques still have many defects, mainly including lack of suitable seed cells, low survival rate and low differentiation rate after transplantation. In this context, extracellular matrix (ECM), as myocardial tissue engineering scaffold materials, has gained increasing attention and become a frontier and focus of medical research in recent years. ECM is no longer merely regarded as a scaffold or a tissue, but plays an important role in providing essential signals to influence major intracellular pathways such as cell proliferation, differentiation and metabolism. The involved models of ECM can be classified into following types:natural biological scaffold materials, synthetic polymer scaffold materials and composite scaffold materials with more balanced physical and biological properties. This review mainly introduces research progress of ECM in myocardial tissue engineering and ECM materials.
Objective Choose polylactide-co-glycolide/hydroxyapatite (PLGA/HA) and porous phosphate calcium (PPC) as the object that we will study, compare their degradabality and choose one as a suitable scaffold for rib reconstruction. Methods All the experiments were divided into PLGA/HA group and CPC group. Degradabality experiment in exvivo: put the two scaffold which have the same size into 0.9% NaCl, keep sterile, then put the container into warm cage,get out and weigh them in 2, 4, 8, 12 and 24 weeks, compare the different speed of the two scaffold. Degradability experiment in vivo: put the two scaffold which have the same size under the skin of the rabbit, and weigh them in 2, 4, 8, 12 and 24 weeks, the tissue around the scaffold was examinzed by HE and the scaffold was examined by electron scanning microscope. Results Micro-CT and Scanning electron microscopy shows that CPC group had better structure (1101.2228±0.6184 mg/ccm vs. 1072.5523±0.7442 mg/ccm)and porosity(70.26%±0.45% vs.72.82%±0.51%)than PLGA/HA group; The result of degradabality experiment in vitro shows that the speed of the two scaffolds was slow. It is at 24 weeks that the degradability is obvious,and the PLGA/HA group degraded a lot which was 60%. The result of degradabality experiment in vivo shows that the speed of degradabality of PLGA/HA group was faster than that is in the 0.9% Nacl, also was faster than that of CPC group which was 96%.The reponse of tissue around the PLGA/HA was more sever than that of CPC group which is in favour of the growth of cells. Conclusion As for the reconstruction of large defect of rib, CPC is more suitable than PLGA/HA.
Objective To study and test novel hybrid valves in vitro and in vivo, and provide basis for clinical use in future. Methods The hybrid valves were fabricated from decellularized porcine aortic valves coated with poly (3-hydroxybutyrate-co-3hydroxyhexanoate, PHBHHx).(1)In the mechanical test in vitro, the uniaxial tensile biomechanics test of the fresh (n=12), uncoated (n=12) and hybrid valve leaflets (n=12) were investigated. (2)In study in vivo, hybrid valves(n=5) implanted in pulmonary position in sheep without cardiopulmonary bypass. Uncoated grafts (n=5) used as control. The specimens of the hybrid or uncoated valve in sheep were explanted and examined by scanning electron microscopy, histology, calcium content and immunofluorescence staining 18 weeks after surgery. Results The mechanical test in vitro revealed that coating with PHBHHx increased maximal tensile strength of hybrid valves compared with the fresh and uncoated state (P<0.05). The results in vivo indicated the hybrid valves maintained original shape and softness. Immunofluorescence staining for CD31 confirmed that the surface of hybrid valve was covered by confluent CD31+ cells.The interstitium of hybrid valve indicated that smooth muscle actin (SMA)+ cells population were similar to native valvular tissue. The calcium content of hybrid valve was significantly lower than that of uncoated valve leaflets (P<0.05). Conclusion Decellularized porcine aortic valves coated with PHBHHx have good biological and biomechanical characteristics. The hybrid valve may provide superior valve replacement with current techniques.
Objective To observe whether Cyclo-RGDfK (Arg-Gly-Asp-D-Phe-Lys) could enhance the adhesion of myofibroblast to decellularized scaffolds and upregulate the expression of Integrin αVβ3 gene. Methods Myofibroblast from the rat thoracic aorta was acquired by primary cell culture. The expression of Vimentin and α-smooth muscle actin(α-SMA) has been detected by immunoflurescent labeling. Decellularized valves have been randomly divided into three groups (each n=7). Group A (blank control): valves do not receive any pretreatment; Group B: valves reacted with linking agent NEthylN(3dimethylaminopropyl)carbodiimide hydrochloride (EDC) for 36 hours before being seeded; Experimental group: Cyclo-RGD peptide has been covalently immobilized onto the surface of scaffolds by linking agent EDC. The fifth generation of myofibroblast has been planted on the scaffolds of each group. The adhesion of myofibroblast to the scaffolds was evaluated by HE staining and electron scanning microscope. The expression of Integrin αVβ3 was quantified by halfquantitative reverse transcriptionpolymerase china reaction (RT-PCR). Results We can see that myofibroblast has exhibited b positive staining for Vimentin and α-SMA. Besides, it has been shown that the expression of Integrin αVβ3 was much higher in the experimental group than that of the group A and group B(Plt;0.05). There was no statistically difference in group A and group B (P=0.900). Conclusion RGD pretreatment does enhance the adhesive efficiency of seeding cells to the scaffolds and this effect may be related to the upregulation of Integrin αVβ3.
Objective Engineer heart tissue (EHT) was constructed with mesenchymal stem cells (MSCs) and poly lacticacidCOglycolic acid (PLGA), and grafted onto the surface of myocardial infarction rats. We hypothesized that great omentum wrapping would increase EHT blood supply and ameliorate EHT microenvironment which is in favor of cardiac collagen remodling and heart function. We hope that omentun wrapped EHT could provide a valuable strategy for surgically myocardial infarction therapy. Methods MSCs were isolated from SD rats.Eight weeks after SD rats were subjected to left anterior descending (LAD) ligation, 18 rats were enrolled and divided into three groups, group A(n=6): great omentum wrapped MSCsPLGA EHT implantation; group B (n=6):MSCsPLGA EHT implantation; control group (n=6): the myocardial infarction; the sham group (n=6): only opened and closed chest, underwent LAD ligation, but no EHT implantation. Four weeks after transplantation, the following variables were evaluated: specimen stained with picrosirius red, left ventricle function evaluated by echocardiography, infarction ventricular wall motion by color kinesis (CK). Results Hearts of group A showed significantly less fibrosis than group B and control group (Plt;0.05). Infarction ventricular wall motion assessed by CK indicated significantly improvement in group A compared with group B and control group (Plt;0.05). Four weeks after transplantation, cardiac echocardiography showed left ventricle ejection fraction was lower in control group and group B compared with group A (Plt;0.05). Conclusion Transplantation of MSCsPLGA EHT with great omentum wrapping ameliorated infarction ventricular collagen remodeling, ameliorated infarction ventricular wall motion and preserved left ventricular function.
Objective To observe expression of human antithrombin Ⅲ (hAT-Ⅲ) gene in vascular endotheliallike cells(VELCs) after transfected. Methods Human bone marrow mesenchymal stem cells(BMMSCs) were isolated, cultured and proliferated in vitro, and were differentiated into VELCs. Then, the VELCs were divided into experimental group cells and control group cells randomly. Plasmid DNA with hAT-Ⅲ gene was transfected into VELCs by liposome mediate. At last, the hAT-Ⅲ expression was determined by reverse transcriptpolymerase chain reaction(RT-PCR), immunohistochemical stain(IHCS), Westernblotting and chromogenic substrate assay at 72h and 96h respectively. In the control group, the plasmid DNA was replaced by TE buffer, and the other methods were the same as the experimental group. Results RT-PCR showed that the specific DNA fragment of hAT-Ⅲ could be amplifed in the experimental group cells, none in the control group. IHCS showed positive expression of hAT-Ⅲ in the experimental group cells, negative in the control group. Westernblotting showed that the specific band of hAT-Ⅲ could be detected in the experimental group cells culture fluid, none in the control group. Chromogenic substrate assay showed that the hAT-Ⅲ activity of the experimental group cells was 9.50%±1.52%, the control group was 1.83%±1.17%, there was statistically difference between two groups(t=7.910,Plt;0.01). Conclusion The hAT-Ⅲ gene could be transfected into VELCs and expressed successfully.
The autograft and non-autograft cannot meet the needs of clinical vascular surgery. Since there are possibilities of thrombus formation in artificial vascular grafts, the methods for deposing the graft using physical and chemical ways or simply seeding with endothelial cells cannot produce satisfactory grafts for vascular operations until now. In order to increase the anticoagulative capacity of artificial vascular graft, it is rational to use genetic engineering methods modifying the endothelial cells to make it express anticoagulative factors stably. Although seeding artificial graft with the genetically engineered endothelial cells can possibly produce a satisfactory graft for vascular surgery, some problems still need to be solved.
In the past fifty more years, many research results have been achieved in the field of artificial esophagus which has been a major subject of surgical study on esophagus. Unfortunately,a very satisfactory artificial esophagus has not been found due to lack of proper artificial materials and problems of postoperative complications which results in great hindrance to applying them to clinical purpose. The current research focuses on artificial esophaguses constructed with acellular matrix as well as constructed through tissue engineering,furthermore,how to prevent and cure postoperative complications is still the main difficulty. This paper gives an overview of the recent study results,points in dispute, present status of research and the recent advances, and an overview to the future of artificial esophagus.