TGF-β3与TIMP-2联合转染兔骨髓间充质干细胞复合丝素蛋白/壳聚糖生物支架修复兔软骨缺损(英文)

目的:TGF-β3广泛存在于骨组织、软骨组织中,能诱导体外培养的间充质干细胞向软骨分化、生长。TIMP-2能抑制MMP对软骨基质的降解,保护新生软骨组织。本实验探讨单纯TGF-β3和TGF-β3,TIMP-2联合转染兔骨髓间充质干细胞复合丝素蛋白壳聚糖/(silk fibrin/chitosan,SF/CS)生物支架植入动物体内修复兔膝关节软骨缺损的可行性及效果差异。方法:将新西兰大白兔20只分为4组,每组5只(支架组、未转染组、reAAV-TGF-β3转染组、reAAV-TGF-β3,reAAV-TIMP-2联合转染组)。在无菌条件下取兔第三代对数生长期骨髓间充质干细胞(bone marrow mesenchymal stem cells,BMSCs),用携带目的基因的重组腺相关病毒进行转染,将转染成功的BMSCs与SF-CS生物支架复合,分别植入兔膝关节软骨缺损处:未转染组植入SF-CS生物支架,未转染组植入未转染的BMSCs复合SF-CS生物支架,reAAV-TGF-β3转染组植入reAAV-TGF-β3转染的BMSCs复合SF-CS生物支架,reAAV-TGF-β3,TIMP-2联合转染组植入reAAV-TGF-β3,TIMP-2联合转染的BMSCs复合SF-CS生物支架。两月后处死家兔,肉眼观察以及HE染色评定缺损软骨修复情况。并进行软骨细胞特征性染色即甲苯胺蓝染色及II型胶原免疫组化染色鉴定。结果:两个月后除支架组外各实验组兔膝关节软骨缺损处均有软骨样物质形成,且联合转染组诱导的新生成分更接近缺损处周围正常软骨。联合转染组与reAAV-TGF-β3转染组;联合转染组与未转染组;reAAV-TGF-β3转染组与未转染组的评分差异均具有统计学意义(P0.05)。HE染色结果提示联合转染组软骨修复效果较单纯TGF-β3转染组更好。结论:单纯TGF-β3转染兔骨髓间充质干细胞对兔膝关节软骨缺损有修复作用,TGF-β3与TIMP-2联合转染组修复缺损效果更明显,提示TIMP-2与TGF-β3具有协同效应。     

软骨细胞联合BMP/bFGF移植对关节软骨损伤的修复作用

目的：探讨同种异体软骨细胞移植联合骨形态发生蛋白（BMP）/碱性成纤维细胞生长因子（bFGF）对关节软骨损伤的修复作用。方法：取24只14周龄成年大白兔,随机分为A、B、C、D组,每组6只,于双侧膝关节软骨处制作软骨缺损模型,A组采用软骨细胞移植联合应用BMP/bFGF处理,B组采用单纯软骨细胞移植,C组采用单纯BMP/bFGF修复,D组采用磷酸盐缓冲液（PBS）作为阴性对照,于处理后8、12、24周行形态学、电镜观察及组织学评分。结果：8周时,A组关节修复面与周围结合紧密,可见大量软骨细胞出现,电镜下有软骨基质形成;B、C组仅有少量软骨细胞;D组未见修复。12周时,A组关节修复面与周围组织界限模糊,软骨细胞增殖活跃,电镜下可见成熟软骨基质;B、C组修复块周围有肉芽组织生成,电镜下可见未成熟的软骨基质出现;D组可见肉芽组织形成。24周时,A组修复面周围组织融合,电镜下软骨细胞纵行排列;B、C组关节面修复不完全,电镜下软骨细胞分布不均;D组见大量肉芽组织形成。24周时,A组组织学评分（1.87±0.65）,明显低于B组（3.49±0.71）、C组（3.43±0.83）组和D组（13.45±0.97）,差异均有统计学意义（P〈0.05）,B、C组均明显低于D组,差异有统计学意义（P〈0.05）,B、C组之间比较无明显差异。结论：软骨细胞联合BMP/bFGF移植能够促进软骨生长,提高软骨损伤的修复质量。     

自体ADSCs复合PRF修复家兔耳软骨缺损的实验研究

目的:将未诱导的自体脂肪干细胞(ADSCs)与富血小板纤维蛋白(PRF)复合,作为一种全新的软骨修复材料,探讨其对家兔耳软骨全层缺损修复的可行性.方法:取家兔10只,于每只家兔耳部做4处软骨全层缺损,随机分为A、B、C、D组,A组,作为空白对照;B组植入自体ADSCs;C组植入自体PRF;D组植入自体ADSCs与PRF的复合物.分别于术后1月、2月、3月取材,进行大体及HE染色观察,并使用IPP6.0软件对软骨生成量进行半定量分析.结果:HE染色显示,3月后,A组几乎无新生软骨生成,B、C、D三组软骨生成量依次增多,D组尤为明显.IPP6.0统计结果显示,移植物植入3月后,A组软骨缺损修复率为(1.68±0.17)％,B组为(15.4±0.91.)％,C组为(32.0±2.76)％,D组为(85.77±4.88)％.各组间有显著统计学差异,与HE染色结果相符.结论:未诱导的自体ADSC s复合自体PRF作为一种全新的软骨修复材料,可以有效的修复家兔耳软骨全层缺损,具有潜在的临床应用价值.     

深低温冻存组织工程化软骨在关节软骨缺损修复的应用

目的：探讨经深低温冻存组织工程化软骨修复关节软骨缺损的可行性。方法：分离收集3周龄新西兰大白兔关节软骨细胞进行体外培养,接种于PGA三维支架材料上,复合物体外培养1周后冻存,冻存1个月后解冻、复苏及体外培养,1周后接种于已建立的双侧兔膝关节软骨缺损模型的膝关节软骨缺损处,并设对照组。分别于手术后4周、8周、12周行大体标本及组织观察。结果：大体观察结果表明,实验组与对照组缺损处均由软骨组织修复;组织学观察可以见到实验组和对照组关节软骨缺损处有密集的软骨细胞,均有软骨生成及基质分泌,两组差异无统计学意义。结论：应用深低温冻存组织工程化软骨修复关节软骨缺损的方法是有效可行的,为其进一步临床应用提供了实验依据。     

自体软骨细胞移植技术治疗膝关节软骨缺损的研究进展

膝关节软骨缺损发病率高,且自身修复能力有限。治疗膝关节软骨缺损的传统方法包括钻孔术、微骨折术、自体骨软骨移植术。然而,钻孔术和微骨折术治疗后缺损区生成的是纤维软骨,而不是正常的透明软骨,两者在力学强度、硬度、耐磨损性等多方面存在很大差距。自体骨软骨移植术可生成正常的透明软骨,但存在供体有限、不适合进行大面积软骨缺损治疗等多方面缺点在临床方面应用受限。近年来,自体软骨细胞移植技术发展迅速,越来越多的病人接受此治疗方法并获得良好效果,引起人们广泛关注。本文根据近年来国内外的各项相关研究成果进行总结,阐述膝关节软骨缺损的各种治疗方法,着重介绍自体软骨细胞移植技术。第三代自体软骨细胞移植技术生成的软骨以透明软骨为主,符合关节生物力学要求,且避免了第一代、第二代自体软骨细胞移植的术后并发症,成为治疗膝关节大面积软骨缺损安全有效的治疗方法。另外,本文就软骨细胞支架材料的发展、移植物术后的转归等问题提出进一步设想。     

骨痹消对兔骨关节炎软骨细胞凋亡的影响

目的探讨中药早期治疗对兔实验性膝关节骨性关节炎(KOA)软骨细胞凋亡的影响。方法参照Okazaki等[1]伸膝制动OA动物模型法造模,随机分为正常组(A组)、模型组(B组)、骨痹消组(C组),于治疗6周、10周后测各组兔血清NO水平变化;软骨电镜结构及TUNEL法软骨细胞凋亡指数(AI)。结果 B组血清NO水平逐渐升高,C组有不同程度的降低;B组电镜下6周时可见凋亡细胞,10周可见凋亡小体;TUNEL法细胞凋亡原位检测:B组软骨细胞AI明显增高。治疗后C组下降明显,10周时与B组相比具极显著差异(P0.01)。结论骨痹消在一定程度上阻断软骨细胞凋亡,减少细胞凋亡数量,促进软骨的修复。     

rhBMP-2诱导异位软骨修复重建兔气管缺损的实验研究

目的：探讨重组人骨形成蛋白-2（rhBMP-2）作为激活物诱导异位软骨修复并重建免气管缺损的可行性。方法：取24只新西兰大白兔,制备气管前壁软骨1／3缺损模型。随机分为A、B组,每组12只,A组为实验组,在气管缺损处前壁颈前肌肉修补,多点注射rhBMP-2;B组于气管软骨缺损部位直接颈前肌群修补。术后观察动物一般情况,于4、8、12周取材进行大体观察、HE染色观察重建区域情况。结果：术后A组动物均存活至实验完成,B组因气道感染及气道分泌物堵管潴留致使实验兔死亡,其余动物出现皮下气肿,呼吸不畅等情况。组织学观察A组有明显的新生软骨细胞及少量软骨样组织,可见结缔组织包绕,周围肌肉组织完整,排列整齐,未见明显坏死组织,有少量淋巴细胞浸润。B组未见软骨组织生成,可见大量肉芽组织增生,结缔组织排列紊乱,伴少量坏死组织,大量淋巴浸润。结论：rhBMP-2可通过注射到颈前肌肉修补肌群中诱导软骨细胞和软骨样组织生成,减轻炎症反应,联合颈前肌瓣修复重建气管缺损能充分维持修复重建后的气道形态,具有减少术后皮下气肿、气管狭窄的作用,有望用于临床修复重建气管纽织缺损。     

RGD多肽修饰钙磷陶瓷支架材料对骨质疏松兔成骨能力及骨功能影响的机制研究

摘要 目的：探究RGD多肽修饰钙磷陶瓷支架材料对骨质疏松（osteoporosis, OP）兔成骨能力和骨功能的影响极其可能的作用机制。方法：选取40只雌性SPF级新西兰大白兔，随机分为A组（正常对照组）和B组（OP组），每组各20只，再将A组随机分为A1组：sham组、A2组：sham+HA组、A3组：sham+BCP组、A4组：sham+RGD-BCP组，每组5只；B组随机分为B1组：OP组、B2组：OP+HA组、B3组：OP+BCP组和B4组：OP+RGD-BCP组，每组5只。B组采用去势法制备OP模型，检测相关指标。结果：A组兔术前和术后3个月时BMD无变化（P>0.05），B组兔术后3个月时的BMD值较术前下降（P<0.05）。自第4 d开始，A组和B组RGD-BCP支架材料组细胞的OD值高于HA和BCP支架材料（P<0.05），且B组之间的差异较A组更大（P<0.05）。Western Blot分析显示，A、B两组中RGD-BCP中整合素avβ3的表达高于HA和BCP（P<0.05），且B组之间的差异较A组更大（P<0.05）。B4和A4组p38 MAPK蛋白的相对表达均低于、Wnt5a和β-catenin表达均高于B2、B3和A2、A3组(P<0.05)，此外，A4组p38 MAPK蛋白的相对低于、Wnt5a和?茁-catenin表达高于B4组(P<0.05)。结论：RGD-BCP对兔BMSCs具有良好的相容性和吸附作用，对OP模型兔更显著；且RGD-BCP的机制可能与调控p38 MAPK/Wnt5a/β-catenin信号通路有关，为OP合并骨缺损的修复提供了新的思路和理论依据。     

深低温冻存组织工程化软骨在喉狭窄功能重建中的应用

目的：探讨低温保存组织工程化软骨在喉狭窄功能重建中的应用价值。方法：取3周龄新西兰兔关节软骨细胞,体外培养,取第2代对数生长期培养细胞,制成细胞悬液,调整软骨细胞悬液浓度约为5×10^7个／ml左右,接种于PGA三维支架材料上,复合物体外培养2周后冻存,冻存6个月后解冻复苏,再行体外培养观察,2周后接种于已建立的喉甲状软骨缺损模型的软骨缺损处,并设对照组。术后12周取材,行大体及组织学观察。结果：经低温冻存的组织工程化软骨生长良好,组织学观察有软骨形成,与周围软骨组织结合紧密,与非冻存组相比差异无统计学意义。结论：深低温冻存对组织工程化软骨的生物活性无明显的影响,低温冻存的组织工程化软骨可用于喉软骨缺损的修复,重建喉功能。     

rhBMP-2 诱导异位软骨修复重建兔气管缺损的实验研究

目的:探讨重组人骨形成蛋白-2(rhBMP-2)作为激活物诱导异位软骨修复并重建兔气管缺损的可行性。方法:取24只新西兰大白兔,制备气管前壁软骨1/3缺损模型。随机分为A、B组,每组12只,A组为实验组,在气管缺损处前壁颈前肌肉修补,多点注射rhBMP-2;B组于气管软骨缺损部位直接颈前肌群修补。术后观察动物一般情况,于4、8、12周取材进行大体观察、HE染色观察重建区域情况。结果:术后A组动物均存活至实验完成,B组因气道感染及气道分泌物堵管潴留致使实验兔死亡,其余动物出现皮下气肿,呼吸不畅等情况。组织学观察A组有明显的新生软骨细胞及少量软骨样组织,可见结缔组织包绕,周围肌肉组织完整,排列整齐,未见明显坏死组织,有少量淋巴细胞浸润。B组未见软骨组织生成,可见大量肉芽组织增生,结缔组织排列紊乱,伴少量坏死组织,大量淋巴浸润。结论:rhBMP-2可通过注射到颈前肌肉修补肌群中诱导软骨细胞和软骨样组织生成,减轻炎症反应,联合颈前肌瓣修复重建气管缺损能充分维持修复重建后的气道形态,具有减少术后皮下气肿、气管狭窄的作用,有望用于临床修复重建气管组织缺损。     

人脐带间充质干细胞抑制卵巢癌的初步研究

目的:从足月剖腹产分娩新生儿脐带中分离出人脐带间充质干细胞(UC-MSCs),探讨其在体外促进SKOV3卵巢癌细胞凋亡,抑制其增殖的作用。方法:新鲜人脐带洗净后剥离动静脉及脐带外膜,得到脐带Wharton's胶。采用组织块贴壁法分离、纯化得到UC-MSCs细胞,光镜下观察UC-MSCs细胞的形态及贴壁生长情况。收集UC-MSCs细胞培养上清,加入SKOV3细胞共培养后,观察不同作用时间(12 h,24 h,36 h,48 h,60 h,72 h)其体外促进SKOV3卵巢癌细胞凋亡,抑制其增殖的作用。结果:光镜下UC-MSCs细胞成长梭状,单核,并成放射或漩涡状排列。PI染色提示,随着UC-MSCs细胞培养上清对SKOV3卵巢癌细胞作用时间的增加,其发生凋亡的细胞数量增多,且具有统计学意义(P0.05)。MTT实验提示SKOV3细胞增殖活力随UC-MSCs细胞培养上清作用时间的增加而显著下降(P0.05),共培养24 h,48 h,72 h的抑制率分别为17.08%,35.36%,46.83%。结论:UC-MSCs在体外具有明显促进SKOV3卵巢癌细胞凋亡,抑制其增殖的作用。     

Tissue engineering and cartilage

Human articular cartilage is an avascular structure, which, when injured, poses significant hurdles to repair strategies. Not only does the defect need to be repopulated with cells, but preferentially with hyaline-like cartilage.Successful tissue engineering relies on four specific criteria: cells, growth factors, scaffolds, and the mechanical environment. The cell population utilized may originate from cartilage itself (chondrocytes) or from growth factors that direct the development of mesenchymal stem cells toward a chondrogenic phenotype. These stem cells may originate from various mesenchymal tissues including bone marrow, synovium, adipose tissue, skeletal muscle, and periosteum. Another unique population of multipotent cells arises from Wharton''s jelly in human umbilical cords. A number of growth factors have been associated with chondrogenic differentiation of stem cells and the maintenance of the chondrogenic phenotype by chondrocytes in vitro, including TGFβ; BMP-2, 4 and 7; IGF-1; and GDF-5.Scaffolds chosen for effective tissue engineering with respect to cartilage repair can be protein based (collagen, fibrin, and gelatin), carbohydrate based (hyaluronan, agarose, alginate, PLLA/PGA, and chitosan), or formed by hydrogels. Mechanical compression, fluid-induced shear stress, and hydrostatic pressure are aspects of mechanical loading found in within the human knee joint, both during gait and at rest. Utilizing these factors may assist in stimulating the development of more robust cells for implantation.Effective tissue engineering has the potential to improve the quality of life of millions of patients and delay future medical costs related to joint arthroplasty and associated procedures.Key words: cartilage repair, gene therapy, growth factors, biomaterials, tissue engineering, stem cells, chondrocyte     

Differentiation of Human Umbilical Cord Matrix Mesenchymal Stem Cells into Neural-Like Progenitor Cells and Maturation into an Oligodendroglial-Like Lineage

Mesenchymal stem cells (MSCs) are viewed as safe, readily available and promising adult stem cells, which are currently used in several clinical trials. Additionally, their soluble-factor secretion and multi-lineage differentiation capacities place MSCs in the forefront of stem cell types with expected near-future clinical applications. In the present work MSCs were isolated from the umbilical cord matrix (Wharton''s jelly) of human umbilical cord samples. The cells were thoroughly characterized and confirmed as bona-fide MSCs, presenting in vitro low generation time, high proliferative and colony-forming unit-fibroblast (CFU-F) capacity, typical MSC immunophenotype and osteogenic, chondrogenic and adipogenic differentiation capacity. The cells were additionally subjected to an oligodendroglial-oriented step-wise differentiation protocol in order to test their neural- and oligodendroglial-like differentiation capacity. The results confirmed the neural-like plasticity of MSCs, and suggested that the cells presented an oligodendroglial-like phenotype throughout the differentiation protocol, in several aspects sharing characteristics common to those of bona-fide oligodendrocyte precursor cells and differentiated oligodendrocytes.     

S100A6 is secreted from Wharton's jelly mesenchymal stem cells and interacts with integrin β1

S100A6 is a calcium binding protein belonging to the S100 family. In this work we examined the function of extracellular S100A6. Using mesenchymal stem cells isolated from Wharton's jelly of the umbilical cord (WJMS cells) we have shown that S100A6 is secreted by these cells, and when added to the medium, increases their adhesion and inhibits proliferation. The search for a potential target/receptor of S100A6 in the membrane fraction of WJMS cells allowed us to identify some proteins, among them integrin β1, which interacts with S100A6 in a calcium dependent manner. The interaction between S100A6 and integrin β1, was then confirmed by ELISA using purified proteins. Applying specific antibodies against integrin β1 reversed the effect on cell adhesion and proliferation observed in the presence of S100A6 which indicates that S100A6 exerts its function due to interaction with integrin β1. Since the data show the influence of extracellular S100A6 on cells isolated from Wharton's jelly, our results might help to establish molecular mechanisms leading to some pathologies characteristic for this tissue.     

Endothelium Trans Differentiated from Wharton's Jelly Mesenchymal Cells Promote Tissue Regeneration: Potential Role of Soluble Pro-Angiogenic Factors

Background

Mesenchymal stem cells have a high capacity for trans-differentiation toward many adult cell types, including endothelial cells. Feto-placental tissue, such as Wharton''s jelly is a potential source of mesenchymal stem cells with low immunogenic capacity; make them an excellent source of progenitor cells with a potential use for tissue repair. We evaluated whether administration of endothelial cells derived from mesenchymal stem cells isolated from Wharton''s jelly (hWMSCs) can accelerate tissue repair in vivo.

Methods

Mesenchymal stem cells were isolated from human Wharton''s jelly by digestion with collagenase type I. Endothelial trans-differentiation was induced for 14 (hWMSC-End14d) and 30 (hWMSC-End30d) days. Cell phenotyping was performed using mesenchymal (CD90, CD73, CD105) and endothelial (Tie-2, KDR, eNOS, ICAM-1) markers. Endothelial trans-differentiation was demonstrated by the expression of endothelial markers and their ability to synthesize nitric oxide (NO).

Results

hWMSCs can be differentiated into adipocytes, osteocytes, chondrocytes and endothelial cells. Moreover, these cells show high expression of CD73, CD90 and CD105 but low expression of endothelial markers prior to differentiation. hWMSCs-End express high levels of endothelial markers at 14 and 30 days of culture, and also they can synthesize NO. Injection of hWMSC-End30d in a mouse model of skin injury significantly accelerated wound healing compared with animals injected with undifferentiated hWMSC or injected with vehicle alone. These effects were also observed in animals that received conditioned media from hWMSC-End30d cultures.

Conclusion

These results demonstrate that mesenchymal stem cells isolated from Wharton''s jelly can be cultured in vitro and trans-differentiated into endothelial cells. Differentiated hWMSC-End may promote neovascularization and tissue repair in vivo through the secretion of soluble pro-angiogenic factors.     

Nucleus pulposus repair with cultured autologous elastic cartilage derived chondrocytes

Low back pain is one of the most common medical conditions in the Western world. Disc degeneration, an inevitable process of ageing, is one of the major causes of low back pain. Autologous chondrocyte transplantation (ACT) is an increasingly popular method of addressing pathological disorders of cartilage. The purpose of our study was to determine whether autologous chondrocytes from elastic cartilage could survive and synthesise a cartilage specific matrix in the intervertebral disc of rabbits. Sixteen lumbar intervertebral discs (IVD) of New Zealand White rabbits were analysed. In 6 IVD, the nucleus pulposus was evacuated and replaced with tissue engineered autologous chondrocytes from auricular cartilage. In the second group, only the nucleus pulposus was evacuated from 6 IVD, with no chondrocytes implantation. Four non-operated IVD were used as a control. Six months after the operation, the animals were euthanized and the IVD were analysed histologically. Autologous cartilage implants were well tolerated by the host for up to six months in vivo. There was only hyaline-like cartilage in the place of the nucleus pulposus. We could not detect any elastic fibres in the new cartilage matrix. In IVD from which only the nucleus pulposus was evacuated and no chondrocytes were implanted, just fibrous tissue was found instead of nucleus pulposus. The overall histological analysis of new cartilage produced after implantation in our study confirmed the hypothesis that ACT from auricular cartilage can be implanted into the IVD instead of the nucleus pulposus and that a significant percentage of implanted chondrocytes survive and produce hyaline-like cartilage.     

Proliferation and differentiation potential of chondrocytes from osteoarthritic patients

Autologous chondrocyte transplantation (ACT) has been shown, in long-term follow-up studies, to be a promising treatment for the repair of isolated cartilage lesions. The method is based on an implantation of in vitro expanded chondrocytes originating from a small cartilage biopsy harvested from a non-weight-bearing area within the joint. In patients with osteoarthritis (OA), there is a need for the resurfacing of large areas, which could potentially be made by using a scaffold in combination with culture-expanded cells. As a first step towards a cell-based therapy for OA, we therefore investigated the expansion and redifferentiation potential in vitro of chondrocytes isolated from patients undergoing total knee replacement. The results demonstrate that OA chondrocytes have a good proliferation potential and are able to redifferentiate in a three-dimensional pellet model. During the redifferentiation, the OA cells expressed increasing amounts of DNA and proteoglycans, and at day 14 the cells from all donors contained type II collagen-rich matrix. The accumulation of proteoglycans was in comparable amounts to those from ACT donors, whereas total collagen was significantly lower in all of the redifferentiated OA chondrocytes. When the OA chondrocytes were loaded into a scaffold based on hyaluronic acid, they bound to the scaffold and produced cartilage-specific matrix proteins. Thus, autologous chondrocytes are a potential source for the biological treatment of OA patients but the limited collagen synthesis of the OA chondrocytes needs to be further explained.     

1950 MHz射频电磁场对人脐带间充质干细胞增殖和成骨分化的影响研究

目的:间充质干细胞(Mesenchymal stem cells,MSCs)具有广阔的临床应用前景,但由于其体外增殖和定向分化等问题,制约了其进一步应用。本研究拟探讨1950MHz射频电磁场(Radio-frequency electromagnetic fields,RF-EMF)对人脐带间充质干细胞(Human umbilical cord mesenchymal stem cells,hUC-MSCs)增殖和成骨方向分化的影响,以期为MSCs的体外增殖和定向分化提供一条新途径。方法:华通氏胶组织块法分离培养人脐带间充质干细胞,流式细胞仪检测间充质干细胞特异性标志物。选择鉴定后的第3至第6代(P3-P6)hUC-MSCs用于实验。将hUC-MSCs细胞暴露或假暴露于频率为1950 MHz,比吸收率(Specific absorption rate,SAR)分别为0.5,1.0和2.0 W/kg的RF-EMF中,每天暴露1 h(5 min开,10 min关),连续暴露7 d。暴露结束后,流式细胞仪检测细胞周期,免疫荧光检测增殖相关蛋白Ki67表达,连续6天用CCK-8方法检测细胞数。在成骨分化研究中,将P3代的hUC-MSCs随机分为假暴露(sham)组,射频辐射暴露(RF)组,成骨诱导培养基组(Induction medium,OM)和成骨诱导培养基联合射频辐射暴露(OM+RF)组,暴露SAR值为2.0 W/kg,其它参数不变。暴露结束后立即检测细胞的碱性磷酸酶(Alkaline phosphatase,ALP)活性。结果:原代培养的细胞具有MSC典型外观,且表达MSCs特异性表面抗原。与sham组相比,不同SAR值RF暴露后,hUC-MSCs的增殖能力无明显变化,S期细胞比例及Ki67蛋白水平也无显著改变。此外,hUC-MSCs经SAR值为2.0W/kg的RF暴露7 d,与sham组相比其ALP活性无显著变化。与OM组相比,OM+RF组的ALP活性亦无显著改变。结论:华通氏胶组织块法能够培养出纯度较高的间充质干细胞,本实验条件下的1950 MHz射频电磁场对hUC-MSCs的增殖和成骨分化均无显著影响。     

Development and characterization of a human articular cartilage‐derived chondrocyte cell line that retains chondrocyte phenotype

Chondrocytes, the only cell type present in articular cartilage, regulate tissue homeostasis by a fine balance of metabolism that includes both anabolic and catabolic activities. Therefore, the biology of chondrocytes is critical for understanding cartilage metabolism. One major limitation when studying primary chondrocytes in culture is their loss of phenotype. To overcome this hurdle, limited attempts have been made to develop human chondrocyte cell lines that retain the phenotype for use as a good surrogate model. In this study, we report a novel approach to the establishment and characterization of human articular cartilage‐derived chondrocyte cell lines. Adenoviral infection followed by culture of chondrocytes in 3‐dimensional matrix within 48 h post‐infection maintained the phenotype prior to clonal selection. Cells were then placed in culture either as monolayer, or in 3‐dimensional matrix of alginate or agarose. The clones were characterized by their basal gene expression profile of chondrocyte markers. Based on type II collagen expression, 21 clones were analyzed for gene expression following treatment with IL‐1 or BMP‐7 and compared to similarly stimulated primary chondrocytes. This resulted in selection of two clones that retained the chondrocyte phenotype as evidenced by expression of type II collagen and other extra‐cellular matrix molecules. In addition, one clone (AL‐4‐17) showed similar responses as primary chondrocytes when treated with IL‐1 or BMP‐7. In summary, this report provides a novel procedure to develop human articular cartilage‐derived chondrocyte cell lines, which preserve important characteristics of articular chondrocytes and represent a useful model to study chondrocyte biology. J. Cell. Physiol. 222: 695–702, 2010. © 2009 Wiley‐Liss, Inc.