1,25-(OH)_2D_3在骨髓间质成骨细胞与血管内皮细胞联合培养中的价值

目的研究兔骨髓间质成骨细胞(RMSO)与兔肾脏血管内皮细胞(RRVEC)共培养时,1,25-(OH)2D3对细胞活性及碱性磷酸酶(ALP)活性、骨钙素(OCN)含量的影响。方法以相同总细胞数接种24孔细胞培养板,1,25-(OH)2D3作用5d后,MTT比色法测定细胞活性。以相同RM-SO细胞数接种96孔细胞培养板,分别于1,25-(OH)2D3作用3、5、12d时,测定细胞ALP活性、OCN含量。结果各检测时间点1,25-(OH)2D3作用组及与RRVEC共培养组细胞活性、ALP活性和OCN含量均较RMSO单独培养增强(P<0.05)。1,25-(OH)2D3作用于RMSO、RRVEC共培养时,在各检测时间点,细胞活性、ALP活性、OCN含量均进一步增强(P<0.05)。结论1,25-(OH)2D3单独应用可促使RMSO成熟,1,25-(OH)2D3作用于RMSO、RRVEC共培养时,细胞活性、RMSO细胞分化及成骨能力均进一步增强。

活性维生素D促组织工程骨血管化

目的探讨以1,25-(OH)2D3为活性因子,与人骨髓间质成骨细胞(human marrow stromal osteoblast,hMSO)、脐静脉血管内皮细胞(human umbilical vein endothelial cell,hUVEC)、珊瑚羟基磷灰石人工骨(coral hydroxyapatite,CHA)联合构建组织工程骨的异位成骨能力和体内快速血管化能力。方法体外分离、培养hMSO和hUVEC。hMSO以5×105/ml,hUVEC以2.5×105/ml按2∶1比例接种至经1,25-(OH)2D3处理过的CHA上,为实验组;相同比例hMSO和hUVEC接种于单纯CHA作为对照组。体外培养3d后,18只裸鼠背部皮下其中6只双侧均植入实验组组织工程骨1块,6只双侧均植入对照组组织工程骨1块,余6只植入实验组及对照组组织工程骨每侧1块。术后4、8、12周后取材,行大体观察、常规组织学、扫描电镜观察,并行植入物成骨的定量判断和新生血管定量分析。结果组织学观察可见,4周时,各组原始类骨组织均长入支架材料内部,实验组有大量不成熟骨组织伴随众多微血管出现;8周,骨组织成熟与微血管相伴出现;12周,各组均有成熟骨组织出现,实验组有典型骨单位。对照组在各时间点微血管量均少于实验组。扫描电镜观察:4周,实验组大量细胞外基质将细胞包埋,材料表面可见大量微血管并有部分穿入材料内部;对照组虽然细胞外基质也较丰富,但微血管量少;8周,实验组部分材料表面出现了束状条索样的类骨质结构,细胞外基质丰富,可见大量微血管相伴出现;对照组微血管量少,骨组织成熟度亦差。植入物成骨的定量判断,8周实验组为3.10±0.52,对照组为2.30±0.59;12周实验组为4.63±0.55,对照组为3.53±0.62;两时间点两组比较差异均有统计学意义(P<0.05)。新生血管定量分析,4周实验组为28.74%±7.81%,对照组为19.52%±4.57%;8周实验组为24.66%±7.38%,对照组为17.84%±5.22%;两时间点两组比较差异均有统计学意义(P<0.05)。结论1,25-(OH)2D3作为活性因子通过加强hMSO与hUVEC之间的相互作用,增强了构建的组织工程骨的异位成骨能力和快速血管化能力。

1,25-(OH)_2VitD_3促进组织工程骨的血管化和骨化

目的：观察以1，25．（OH）2VitD3为活性因子，与人骨髓间质成骨细胞、脐静脉血管内皮细胞、珊瑚羟基磷灰石人工骨联合构建组织工程骨时，1，25-（OHhVitD3在三维支架上对成骨细胞的作用及构建组织工程骨的体内快速血管化能力和异位成骨能力。方法：（1）实验材料及对象：实验于2005—09／2006—03在苏州大学细胞与基因教研室完成。取SPF级6—8周龄BALB／cnu雄性裸鼠18只，体质量27～32g，骨髓来源于健康成人（志愿者）、新生儿脐带取材时经产妇同意。（2）实验方法及评估：①体外实验：体外分离、培养人骨髓间质成骨细胞和脐静脉内皮细胞。人骨髓间质成骨细胞以5×10^8 L^-1，脐静脉内皮细胞以2．5×10^8 L^-1按2：1比例接种至经1，25-（0H）2VitD3处理过的珊瑚羟基磷灰石人工骨上，作为实验组；相同比例接种于单纯珊瑚羟基磷灰石人工骨上为对照组。体外培养3d后，检测骨钙素含量及碱性磷酸酶活性并始终行光学显微镜观察。②动物实验：18只裸鼠随机摸球法分为两组，9只植入实验组组织工程骨每侧1块，另9只植入对照组组织工程骨每侧1块。术后4，8，12周后取材，行常规组织学、扫描电镜观察，并行植入物新生血管定量分析和成骨的定量判断。结果：纳入裸鼠18只，均进入结果分析。①倒置显微镜下珊瑚羟基磷灰石人工骨周边人骨髓间质成骨细胞、脐静脉内皮细胞均良好生长。组织工程骨构建3d后，骨钙素含量和碱性磷酸酶活性实验组明显高于对照组（P〈0．05）。②组织学观察可见，4周时，各组原始类骨组织均长入支架材料内部。8周时，骨组织成熟与微血管相伴出现。12周时，各组均有成熟骨组织出现。对照组在各时间点微血管量均少于实验组。扫描电镜观察，4周时，实验组大量细胞外基质将细胞包埋，材料表面可见大量微血管并有部分穿入材料内部。对照组虽然细胞外基质也较丰富，但微血管量少。8周时，实验组部分材料表面出现了束状条索样的类骨质结构，可见大量微血管相伴出现。对照组微血管量少。新生血管定量分析显示，4周及8周时两组比较，差异显著（P〈0．05）；植入物成骨的定量判断，8周及12周时两组比较差异均有显著性意义（P〈0．05）。结论：1，25-（OH）2VitD3作为活性因子通过加强人骨髓间质成骨细胞与脐静脉内皮细胞之间的相互作用，增强了构建的组织工程骨的快速血管化能力和异位成骨能力。

CO-TRANSFECTION OF RAT BONE MARROW MESENCHYMAL STEM CELLS WITH HUMAN BMP2 AND VEGF165 GENES

Objective To explore the feasibility and efficacy of lentivirus-mediated co-transfection of rat bone marrow mesenchymal stem cells （MSCs） with human vascular endothelial growth factor 165 （hVEGFI65） gene and human bone morphogenetic protein 2 （hBMP2） gene. Methods The hVEGF165 and hBMP2 cDNAs were obtained from human osteosarcoma cell line MG63 and cloned into lentiviral expression vectors designed to co-express the copepod green fluorescent protein （copGFP）. The expression lentivector and packaging Plasmid Mix were co-transferred to 293TN cells, which produced the lentivirus carrying hVEGF165 （Lv-VEGF） or hBMP2 （ Lv-BMP） , respectively. MSCs of Wistar rats were co-transfected with Lv-BMP and Lv-VEGF （BMP ＋ VEGF group）, or each alone （BMP group and VEGF group）, or with no virus （ Control group）. The mRNA and protein expressions of hVEGF165 and hBMP2 genes in each group were detected by real-time PCR and enzyme linked immunosorbent assay （ELISA）. Results Lentiviral expression vectors carrying hVEGF165 or hBMP2 were correctly constructed and confirmed by restriction endonucleses analysis and DNA sequencing analysis. A transfer efficiency up to 90% was archieved in all the transfected groups detected by the fraction of fluorescent cells using fluorescent microscopy. From the results generated by real-time PCR and ELISA, VEGF165 and BMP2 genes were co-expressed in BMP ＋ VEGF group. No significant difference of BMP2 expression was detected between BMP ＋ VEGF and BMP groups （ P 〉 0. 05）. Similarly, there was no significant difference of VEGF165 expression between BMP ＋ VEGF and VEGF groups （ P 〉 0. 05）. Conclusion VEGF165 and BMP2 genes were successfully co-expressed in MSCs by lentivirus-mediated co-transfection, which provided a further foundation for the combined gene therapy of bone regeneration.

系列可吸收珊瑚羟基磷灰石的制备及作为骨组织工程支架材料的实验研究

目的研制性能稳定的系列可吸收珊瑚羟基磷灰石。方法①珊瑚在高温高压条件下与磷酸氢二铵反应，反应后分析三组转化材料的物相组成和晶体构型。②观察反应产物生物降解情况。进行金属元素分析，了解毒性元素的含量，并对其进行溶血实验、细胞毒性实验和骨相容性实验。结果①在不同条件下进行水热反应，生成不同碳酸钙，羟基磷灰石比例的梯度材料。②此梯度材料保持了多孔网状结构的特点，其小梁超微结构可见表面有一薄层致密的物质。③转化材料生物相容性良好。结论①在不同反应条件下，可形成梯度珊瑚羟基磷灰石材料。②转化材料保持了多孔网状结构，表面有一薄层羟基磷灰石。③转化材料可作为骨组织工程的支架材料。

Osteogenic differentiation of mesenchymal stem cells promoted by overexpression of connective tissue growth factor

Objective:Large segmental bone defect repair remains a clinical and scientific challenge with increasing interest focusing on combining gene transfection with tissue engineering techniques.The aim of this study is to investigate the effect of connective tissue growth factor(CTGF) on the proliferation and osteogenic differentiation of the bone marrow mesenchymal stem cells(MSCs).Methods:A CTGF-expressing plasmid(pCTGF) was constructed and transfected into MSCs.Then expressions of bone morphogenesis-related genes,proliferation rate,alkaline phosphatase activity,and mineralization were examined to evaluate the osteogenic potential of the CTGF gene-modified MSCs.Results:Overexpression of CTGF was confirmed in pCTGF-MSCs.pCTGF transfection significantly enhanced the proliferation rates of pCTGF-MSCs(P<0.05).CTGF induced a 7.5-fold increase in cell migration over control(P<0.05).pCTGF transfection enhanced the expression of bone matrix proteins,such as bone sialo-protein,osteocalcin,and collagen type I in MSCs.The levels of alkaline phosphatase(ALP) activities of pCTGF-MSCs at the 1st and 2nd weeks were 4.0-and 3.0-fold higher than those of MSCs cultured in OS-medium,significantly higher than those of mock-MSCs and normal control MSCs(P<0.05).Overexpression of CTGF in MSCs enhanced the capability to form mineralized nodules.Conclusion:Overexpression of CTGF could improve the osteogenic differentiation ability of MSCs,and the CTGF gene-modified MSCs are potential as novel cell resources of bone tissue engineering.