Repair of articular cartilage defects with a novel injectable in situ forming material in a canine model

We developed an ultra-purified in situ forming gel as an injectable delivery vehicle of bone marrow stromal cells (BMSCs). Our objective was to assess reparative tissues treated with autologous BMSCs implanted using the injectable implantation system into osteochondral defects in a canine model. Forty-eight osteochondral defects in the patella groove of the knee joint were created in 12 adult beagle dogs (two defects in each knee). The defects were divided into a defect group (n = 16), an acellular novel material implantation (material) group (n = 16), and a BMSCs implantation using the current vehicle system (material with BMSCs) group (n = 16). The reparative tissues at 16 weeks postoperatively were assessed through gross, histological, and mechanical analyses. The reparative tissues of the material with BMSCs group were substituted with firm and smooth hyaline-like cartilage tissue that was perfectly integrated into the host tissues. This treatment group obviously enhanced the subchondral bone reconstruction. The compressive modulus of the reparative tissues was significantly higher in the material with BMSCs group than the other groups. This study demonstrated that the implantation of BMSCs using our novel in situ forming material induced a mature hyaline-like cartilage repair of osteochondral defects in a canine model.     

Repairing large porcine full-thickness defects of articular cartilage using autologous chondrocyte-engineered cartilage

Large full-thickness defects of articular cartilage remain a major challenge to orthopedic surgeons because of unsatisfactory results of current therapy. Many methods, such as chondrectomy, drilling, cartilage scraping, arthroplasty, transplantation of chondrocytes, periosteum, perichondrium, as well as cartilage and bone, have been tried to repair articular cartilage defects. However, the results are far from satisfactory. In this study, we applied a tissue-engineering approach to the repair of articular cartilage defects of knee joints in a porcine model. Using isolated autologous chondrocytes, polyglycolic acid (PGA), and Pluronic, we have successfully in vivo-engineered hyaline cartilage and repaired articular cartilage defects. The surface of the repaired defects appeared smooth at 24 weeks postrepair. Histological examination demonstrated a typical hyaline cartilage structure with ideal interface healing between the engineered cartilage and the adjacent normal cartilage and underlying cancellous bone. In addition, glycosaminoglycan (GAG) levels in the engineered cartilage reached 80% of that found in native cartilage at 24 weeks postrepair. Biomechanical analysis at 24 weeks demonstrated that the biomechanical properties of the tissue-engineered cartilage were improved compared with those at an earlier stage. Thus, the results of this study may provide insight into the clinical repair of articular cartilage defects.     

Conditioned Medium from Chondrocyte/Scaffold Constructs Induced Chondrogenic Differentiation of Bone Marrow Stromal Cells

For the application of bone marrow stromal cells (BMSCs) in cartilage tissue engineering, it is imperative to develop efficient strategies for their chondrogenic differentiation. In this study, the conditioned media derived from chondrocyte/scaffold constructs were used to direct chondrogenic differentiation of BMSCs. The porcine articular chondrocytes were seeded on the PGA/PLA scaffolds to form chondrocyte/scaffold constructs and were cultured to form engineered cartilage in vitro. The culture media were collected as conditioned media and used for chondrogenic induction of BMSC pellets (experimental group, Exp.). The chondrocyte pellets and BMSC pellets were cultured routinely as positive control (PC) and negative control (NC), respectively. After 4 weeks, the wet weight and GAG content in Exp. group and PC group were significantly higher than that in NC group. Histological and immunohistochemical analysis showed that cartilaginous tissue was formed with typical cartilage lacuna structure and positive staining of collagen Type II (Col II) in the peripheral area of the BMSC pellets in Exp. group. Gene expression of Sox9, Col II, and COMP in Exp. group and PC group were significantly higher than that in NC group. The growth factors in the conditioned media derived from human costal chondrocytes‐scaffold constructs were tested by protein microassay. The conditioned media contained low levels of TGF‐β1,2,3, IGF‐1 and high levels of IGF‐2, FGF‐4, and IGFBP4,6, and so forth. The soluble factors derived from the engineered cartilage can induce chondrogenic differentiation of BMSCs independently. Many cytokines may function in chondrogenesis in a coordinated way. Anat Rec, 2012. © 2012 Wiley Periodicals, Inc.     

Repair of articular cartilage defect in non-weight bearing areas using adipose derived stem cells loaded polyglycolic acid mesh

The current study was designed to observe chondrogenic differentiation of adipose derived stem cells (ASCs) on fibrous polyglycolic acid (PGA) scaffold stabilized with polylactic acid (PLA), and to further explore the feasibility of using the resulting cell/scaffold constructs to repair full thickness articular cartilage defects in non-weight bearing area in porcine model within a follow-up of 6 months. Autologous ASCs isolated from subcutaneous fat were expanded and seeded on the scaffold to fabricate ASCs/PGA constructs. Chondrogenic differentiation of ASCs in the constructs under chondrogenic induction was monitored with time by measuring the expression of collagen type II (COL II) and glycosaminoglycan (GAG). The constructs after being in vitro induced for 2 weeks were implanted to repair full thickness articular cartilage defects (8 mm in diameter, deep to subchondral bone) in femur trochlea (the experimental group), while scaffold alone was implanted to serve as the control. Histologically, the generated neo-cartilage integrated well with its surrounding normal cartilage and subchondral bone in the defects of experimental group at 3 months post-implantation, whereas only fibrous tissue was filled in the defects of control group. Immunohistochemical and toluidine blue staining confirmed the similar distribution of COL II and GAG in the regenerated cartilage as the normal one. A vivid remolding process with post-operation time was also witnessed in the neo-cartilage as its compressive moduli increased significantly from 50.55% of the normal cartilage at 3 months to 88.05% at 6 months. The successful repair thus substantiates the potentiality of using chondrogenic induced ASCs and PGA/PLA scaffold for cartilage regeneration.     

The maturity of tissue-engineered cartilage in vitro affects the repairability for osteochondral defect

Cartilage tissue engineering using cells and biocompatible scaffolds has emerged as a promising approach to repair of cartilage damage. To date, however, no engineered cartilage has proven to be equivalent to native cartilage in terms of biochemical and compression properties, as well as histological features. An alternative strategy for cartilage engineering is to focus on the in vivo regeneration potential of immature engineered cartilage. Here, we used a rabbit model to evaluate the extent to which the maturity of engineered cartilage influenced the remodeling and integration of implanted extracellular matrix scaffolds containing allogenous chondrocytes. Full-thickness osteochondral defects were created in the trochlear groove of New Zealand white rabbits. Left knee defects were left untreated as a control (group 1), and right knee defects were implanted with tissue-engineered cartilage cultured in vitro for 2 days (group 2), 2 weeks (group 3), or 4 weeks (group 4). Histological, chemical, and compression assays of engineered cartilage in vitro showed that biochemical composition became more cartilagenous, and biomechanical property for compression gradually increased with culture time. In an in vivo study, gross imaging and histological observation at 1 and 3 months after implanting in vitro-cultured engineered cartilage showed that defects in groups 3 and 4 were repaired with hyaline cartilage-like tissue, whereas defects were only partially filled with fibrocartilage after 1 month in groups 1 and 2. At 3 months, group 4 showed striking features of hyaline cartilage tissue, with a mature matrix and a columnar arrangement of chondrocytes. Zonal distribution of type II collagen was most prominent, and the International Cartilage Repair Society score was also highest at this time. In addition, the subchondral bone was well ossified. In conclusion, in vivo engineered cartilage was remodeled when implanted; however, its extent to maturity varied with cultivation period. Our results showed that the more matured the engineered cartilage was, the better repaired the osteochondral defect was, highlighting the importance of the in vitro cultivation period.     

Development of mature cartilage constructs using novel three-dimensional porous scaffolds for enhanced repair of osteochondral defects

In this study, we successfully developed two types of volume-reduced three-dimensional scaffolds, including cushion- and cylinder-shape scaffolds, fabricated from chitosan-based hyaluronic acid hybrid polymer fibers. Using these scaffolds combined with a bioreactor system, we regenerated histologically and mechanically mature cartilage constructs. The final goal of this study was to clarify the ability of this engineered cartilage construct to induce cartilage repair in osteochondral defects. The mature cartilage constructs regenerated with two types of scaffolds were implanted into 5-mm diameter osteochondral defects in the patellar groove of rabbits. At 12 weeks after implantation, the reparative tissues consisted of hyaline-like cartilage with evidence of stable fusion to adjacent native cartilage and normal reconstitution of subchondral bone. The histological score of these tissues significantly outranked the value of untreated tissue. Biomechanically, compression modulus of reparative tissue at 12 weeks postoperatively was comparative to that of normal articular cartilage. Our results indicate that the implantation of constructs with mature cartilage have potential as a better approach for joint resurfacing.     

Tissue engineering of human cartilage and osteochondral composites using recirculation bioreactors

Chondrocytes isolated from human foetal epiphyseal cartilage were seeded dynamically into polyglycolic acid (PGA) scaffolds and cultured in recirculation column bioreactors to produce tissue-engineered cartilage. Several culture techniques with the potential to provide endogenous growth factors and other conditions beneficial for de novo cartilage synthesis were investigated. Osteochondral composite constructs were generated by seeding separate PGA scaffolds with either foetal chondrocytes or foetal osteoblasts then suturing the scaffolds together before bioreactor cultivation. This type of co-culture system provided direct contact between the tissue-engineered cartilage and developing tissue-engineered bone and yielded significant improvements in cartilage quality. In the cartilage section of the composites, the concentrations of glycosaminoglycan (GAG) and total collagen were increased by 55% and 2.5-fold, respectively, compared with control cartilage cultures, while levels of collagen type II were similar to those in the controls. The osteochondral composites were harvested from the bioreactors as single units with good integration between the cartilage and bone tissues. Only the cartilage layer contained GAG while only the bone layer was mineralised. In other experiments, co-culture of tissue-engineered cartilage with pieces of ex-vivo cartilage or ex-vivo bone did not improve the quality of the cartilage relative to control cultures. Addition of 10(-6) M diacerein to the culture medium also had no effect on the properties of engineered cartilage. This work demonstrates the beneficial effects of generating cartilage tissues in contact with developing bone. It also demonstrates the feasibility of producing composite osteochondral constructs for clinical application using recirculation column bioreactors.     

Chondrogenic differentiation of bone marrow-derived mesenchymal stem cells induced by acellular cartilage sheets

Acellular cartilage sheets (ACSs) have been used as scaffolds for engineering cartilage with mature chondrocytes. In this study we investigated whether ACSs possess a chondrogenic induction activity that may benefit cartilage engineering with multipotent stem cells. Bone marrow-derived mesenchymal stem cells (BMSCs) isolated from newborn pigs were expanded in vitro and seeded on ACSs that were then stacked layer-by-layer to form BMSC-ACS constructs. Cells seeded on polyglycolic acid/polylactic acid (PGA/PLA) scaffolds served as a control. After 4 weeks of culture with or without additional chondrogenic factors, constructs were subcutaneously implanted into nude mice for another 4 weeks. Cartilage-like tissues were formed after 4 weeks of culture. However, formation of cartilage with a typical lacunar structure was only observed in induced groups. RT-PCR showed that aggrecan, COMP, type II collagen and Sox9 were expressed in all groups except the non-induced BMSC-PGA/PLA group. At 4 weeks post-implantation, cartilage formation was achieved in the induced BMSC-ACS group and partial cartilage formation was achieved in the non-induced BMSC-ACS group, confirmed by safranin O staining, toluidine blue staining and type II collagen immunostaining. In addition, enzyme-linked immunosorbent assay demonstrated the presence of transforming growth factor-β1, insulin-like growth factor-1 and bone morphogenic protein-2 in ACSs. These results indicate that ACSs possess a chondrogenic induction activity that promotes BMSC differentiation.     

The promotion of cartilage defect repair using adenovirus mediated Sox9 gene transfer of rabbit bone marrow mesenchymal stem cells

Although Sox9 is essential for chondrogenic differentiation and matrix production, its application in cartilage tissue engineering has been rarely reported. In this study, the chondrogenic effect of Sox9 on bone marrow mesenchymal stem cells (BMSCs) in vitro and its application in articular cartilage repair in vivo were evaluated. Rabbit BMSCs were transduced with adenoviral vector containing Sox9. Toluidine blue, safranin O staining and real-time PCR were performed to check chondrogenic differentiation. The results showed that Sox9 could induce chondrogenesis of BMSCs both in monolayer and on PGA scaffold effectively. The rabbit model with full-thickness cartilage defects was established and then repaired by PGA scaffold and rabbit BMSCs with or without Sox9 transduction. HE, safranin O staining and immunohistochemistry were used to assess the repair of defects by the complex. Better repair, including more newly-formed cartilage tissue and hyaline cartilage-specific extracellular matrix and greater expression of several chondrogenesis marker genes were observed in PGA scaffold and BMSCs with Sox9 transduction, compared to that without transduction. Our findings defined the important role of Sox9 in the repair of cartilage defects in vivo and provided evidence that Sox9 had the potential and advantage in the application of tissue engineering.     

凝胶包埋骨髓基质干细胞复合脱钙骨基质修复关节软骨缺损简

目的探索Ⅱ型胶原凝胶包埋的自体骨髓基质干细胞（BMSCs）接于同种异体脱钙骨基质（DBM）材料修复兔关节软骨缺损的效果。方法15只健康成年新西兰大白兔,雌雄不限,体质量约3．0kg,兔龄6。9个月;以Urist方法制作同种异体DBM材料。以Ⅱ型胶原蛋白配制水凝胶．以水凝胶包埋兔BMSCs并接种于同种异体DBM材料,构建组织工程复合物。在新西兰大白兔股骨髁关节面制造软骨缺损。分组进行修复。将健康成年新西兰大白兔27只（雌雄不限,体质量约2．5kg．兔龄3～4个月）共54侧膝关节随机分为Ⅱ型胶原／DBM／BMSCs修复组（实验组）、Ⅱ型胶原／DBM修复组（实验对照组）及空白对照组。于术后4周、8周及12周各处死9只动物,取材对修复组织进行大体及组织学观察,根据Wakitani法对修复组织进行评分．数据输入SPSS11．5软件进行统计学分析,比较各组的评分差异是否具有统计学意义。结果实验组Ⅱ型胶原／DBM／BMSCs植入后形成透明软骨样修复．表面光滑平坦,与周围软骨及软骨下骨结合良好;实验对照组Ⅱ型胶原／DBM植入后有部分软骨样修复：而空白对照组仅有少量纤维性修复。根据组织学评分标准,实验组组织学评分为（20．25±1．64）分,高于实验对照组[（7．46±1．29）分]及空白对照组[（6．00±2．09）分]。结论Ⅱ型胶原自体BMSCs复合同种异体DBM支架材料修复全层关节软骨缺损的效果良好,是一种修复软骨缺损的行之有效的方法。     

Ectopic osteochondral formation of biomimetic porous PVA-n-HA/PA6 bilayered scaffold and BMSCs construct in rabbit

In this work, the novel poly vinyl alcohol/gelatin-nano-hydroxyapatite/polyamide6 (PVA-n-HA/PA6) bilayered scaffold with biomimetic properties for articular cartilage and subchondral bone is developed. Furthermore, when these osteochondral scaffolds were seeded with induced bone mesenchymal stem cells (BMSCs) and implanted at ectopic sites, showed the potential for an engineered cartilage tissue and the corresponding subchondral bone. BMSCs were expanded in vitro and induced to chondrogenic or osteogenic potential by culturing in suitable media for 14 days. Subsequently, these induced cells were seeded into PVA-n-HA/PA6 separately, and the constructs were implanted into the rabbit muscle pouch for upto 12 weeks. Ectopic neocartilage formation in the PVA layer and reconstitution of the subchondral bone which remained confined within the n-HA/PA6 layer with the alteration of the cellular phenotype were identified with Masson's trichrome stain. Simultaneously, the RT-PCR results confirmed the expression of specific extracellular matrix (ECM) markers for cartilaginous tissue, such as collagen type II (Col-II), or alternatively, markers for osteoid tissue, such as collagen type I (Col-I) at the corresponding layers. During ectopic implantation, the underlying subchondral bone layer was completely integrated with the cartilage layer. The result from the ectopic osteochondral scaffolds implantation suggests that PVA-n-HA/PA6 with induced BMSCs is a possible substitute with potential in cartilage repair strategies.     

以转染CDMP1基因的BMSCs修复软骨缺损

 目的 探讨CDMP1基因转染的骨髓间充质干细胞（BMSCs）负载于聚乳酸-羟基乙酸（PLGA）支架上修复喉软骨缺损的能力,并对其修复效果做出初步评估。方法 用反转录聚合酶链式反应（RT-PCR）和免疫印迹法(Western blot)检测hCDMP1mRNA和蛋白的表达;用免疫组织化学方法检测Ⅱ型胶原蛋白(ColⅡ)以及糖胺聚糖(GAG)的表达;将转染前后的细胞支架培养体系移植入兔甲状软骨全层缺损处,从大体、组织学方面观察其对软骨缺损的修复作用。结果 腺病毒感染方法可以将外源hCDMP1基因成功转入BMSCs,并使其获得稳定表达;和对照组比较,转染hCDMP1基因的BMSCs分泌ColⅡ、GAG等软骨特异性基质的能力增强,有促进软骨分化趋势;转染细胞支架复合物可更加有效地修复喉软骨缺损。结论 转染hCDMP1基因的BMSCs/PLGA三维生物支架复合物移植动物体内可修复喉软骨缺损。     

Repair of rabbit osteochondral defects by an acellular technique with an ultrapurified alginate gel containing stromal cell-derived factor-1

The objective of this study was to determine whether the local administration of stromal cell-derived factor-1 (SDF-1) using ultrapurified alginate gel (UPAL gel) could improve reparative tissues of osteochondral defects compared with those without treatment. For the investigation, a full-thickness osteochondral defect 4.5 mm in diameter and 3 mm in depth was created in the patella groove of the distal femur in rabbits. Local expression of SDF-1 protein was temporarily upregulated at 1 week after creating the osteochondral defect. The local administration of SDF-1 enhanced the migration of host cells, mainly bone marrow stromal cells (BMSCs), to the site of the osteochondral defect. In vitro cell migration assay supported this result. In the SDF-1 (UPAL gel containing SDF-1) treatment group, the histological scores and the compressive modulus of reparative tissues were significantly improved compared with the no-treatment and vehicle (UPAL gel without SDF-1) groups. On the other hand, SDF-1 did not influence the cellular proliferation and chondrogenesis of BMSCs. Based on the results obtained here, we speculate that SDF-1 enhances the reparative process of osteochondral injuries not through direct effects on the behavior of host cells, but through increased migration of host cells to the injured site. UPAL gel, as a vehicle material, may play an important role in chondrogenesis of recruited cells, mainly BMSCs. The cell-free approach with local administration of SDF-1 may be an effective strategy for developing a minimally invasive technique for cartilage tissue regeneration.     

Mechanical resistance of biological repair cartilage: comparative in vivo tests of different surgical repair procedures

The former common knowledge that cartilage lesions do not heal has been modified over the last few years due to new technologies. For repair of deeper circumscribed lesions osteochondral press-fit grafting and tissue engineering are used in clinical application. The histological data of the hyaline-like tissue obtained by engineering are just as satisfactory as the surviving grafted hyaline cartilage on top of osteochondral cylinders. But comparative studies are still lacking. To fill the gap and with a view to repairing larger osteoarthritic defects we have performed an in vivo study on 16 goats. Three months after the creation of a full thickness wide cartilage defect on the femoral condyle with harvesting of cartilage samples for tissue cultures we performed secondary cartilage repair procedures on the installed osteoarthritis areas: 1) grafting with autogenic osteochondral press-fit cylinders from the opposite knee, 2) autologous engineered chondrocyte grafting under periosteal flaps, 3) both in combination. The harvesting defects were either left as controls or filled with a hyaluronate fleece. After eight months the repaired areas and the harvesting defects were examined for cartilage stiffness as a novel comparative parameter. Compared to normal the cartilage on top of osteochondral grafts is considerably stiffer. Engineered cartilage is weaker than normal. Spontaneously ingrown fibrous cartilage is much weaker even with a carrier fleece. A combination of osteochondral press-fit grafts with engineered autologous cells restores biomechanical qualities to repaired larger degenerative cartilage defects.     

聚左旋乳酸/壳聚糖纳米纤维三维多孔支架复合骨髓间充质干细胞修复兔骨缺损**△

背景：骨髓间充质干细胞具有向多种间质细胞谱系分化的能力,且支架材料的性能对骨缺损的修复有重要影响。 目的：观察聚左旋乳酸/壳聚糖纳米纤维三维多孔支架复合骨髓间充质干细胞治疗骨缺损。 方法：对骨缺损模型兔分别采用空白植入、髂后上棘自体松质骨移植、聚左旋乳酸/壳聚糖纳米纤维多孔支架移植和复合了骨髓间充质干细胞的聚左旋乳酸/壳聚糖纳米纤维多孔支架移植修复缺损部位。 结果与结论：至移植12周,移植复合了骨髓间充质干细胞的聚左旋乳酸/壳聚糖纳米纤维多孔支架的实验兔的缺损处有骨组织生成,支架材料降解,已完成缺损修复,其修复情况接近松质骨组;髂后上棘自体松质骨移植的实验兔的缺损修复完好,新形成的骨组织较规则;只植入聚左旋乳酸/壳聚糖纳米纤维多孔支架的实验兔有少量骨组织形成,材料部分降解;空白植入的实验兔缺损处无新生骨组织生成,主要由纤维结缔组织填充。说明新型的生物支架材料聚左旋乳酸/壳聚糖纳米纤维三维多孔支架与来源于新西兰大白兔的骨髓间充质干细胞复合培养后,植入同种异体兔股骨髁缺损处,使骨缺损的修复速度加快,表现为较好的体内诱导成骨的作用。     

丝素蛋白/羟基磷灰石材料复合骨髓间充质干细胞构建组织工程化软骨

背景：随着组织工程的兴起,软骨损伤的修复可能性显著地提高,但单一的支架材料均不能符合理想支架,有一定的局限性。 目的：观察骨髓间充质干细胞复合丝素蛋白/羟基磷灰石构建组织工程化软骨的可行性。 方法：体外分离培养骨髓间充质干细胞,并定向诱导成软骨细胞,与丝素蛋白/羟基磷灰石复合培养,构建膝关节胫骨平台全层关节软骨缺损。54只大白兔单侧膝关节全层软骨缺损模型后随机抽签法分为3组,复合组植入细胞-丝素蛋白/羟基磷灰石复合物;材料组植入单纯丝素蛋白/羟基磷灰石,对照组不行任何植入。植入后8,12周CT检查及组织学检查观察软骨缺损修复情况。 结果与结论：植入后8周,复合组关节面不平整,关节间隙增大,形成新生类软骨细胞,基质丰富。材料组关节面塌陷,软骨细胞少量增殖。植入后12周,复合组关节面平整,关节间隙如常。大量软骨细胞出现,与周边软骨色泽一样,支架材料完全降解。材料组关节面不平整,软骨细胞不完全充填,支架材料部分降解。对照组未见修复。提示用骨髓间充质干细胞复合丝素蛋白/羟基磷灰石可形成透明软骨修复动物膝关节全层软骨缺损,显示了丝素蛋白/羟基磷灰石材料作为关节软骨组织工程支架材料的良好生物相容性。     

Use of a biphasic graft constructed with chondrocytes overlying a beta-tricalcium phosphate block in the treatment of rabbit osteochondral defects

To evaluate the ability of a biphasic construct to repair osteochondral defects in articular cartilage, plugs made of chondrocytes in collagen gel overlying a resorbable porous beta-tricalcium phosphate (TCP) block were implanted into defects in rabbit knees. The repair tissue was evaluated at 8, 12, and 30 weeks. Eight weeks after implantation of the biphasic construct, histologic examination showed hyaline-like cartilage formation that was positive for safranin O and type II collagen. At 12 weeks, most of the beta-TCP was replaced by bone, with a small amount remaining in the underlying cartilage. In the cell-seeded layer, the newly formed middle and deep cartilage adjacent to the subchondral bone stained with safranin O, but no staining was observed in the superficial layer. In addition, cell morphology was distinctly different from the deep levels of the reparative cartilage, with hypertrophic cells at the bottom of the cartilaginous layer. At 30 weeks, beta-TCP had completely resorbed and a tidemark was observed in some areas. In contrast, controls (defects filled with a beta-TCP block alone) showed no cartilage formation but instead had subchondral bone formation. These findings indicate that beta-TCP-supported chondrocytes in collagen gel can partially repair isolated articular cartilage osteochondral defects.     

Effects of co-culturing BMSCs and auricular chondrocytes on the elastic modulus and hypertrophy of tissue engineered cartilage

Co-culture of BMSCs and chondrocytes is considered as a promising strategy to generate tissue engineered cartilage as chondrocytes induce the chondrogenesis of BMSCs and inhibit the hypertrophy of engineered cartilage. Because the tissue specific stem/progenitor cells have been isolated from mature tissues including auricular cartilage, we hypothesized that adding stem cells to auricular chondrocytes in co-culture would also enhance the quality of engineered cartilage. In the present study, using the histological assay, biomechanical evaluation, and quantitative analysis of gene expression, we compared different strategies of auricular chondrocytes, BMSCs induction, and co-culture at different ratios on PGA/PLA scaffolds to construct tissue engineered elastic cartilage in vitro and in vivo. The up-regulation of RUNX2 and down-regulation of SOX9 were found in BMSCs chondrogenic induction group, which might imply a regulatory mechanism for the hypertrophy and potential osteogenic differentiation. Engineered cartilage in co-culture 5:5 group showed the densest elastic fibers and the highest Young's modulus, which were consistent with the expression profile of cartilage matrix-related genes including DCN and LOXL2 genes. Moreover, the better proliferative and chondrogenic potentials of engineered cartilage in co-culture 5:5 group were demonstrated by the stronger expression of Ki67 and Dlk1.     

聚羟基烷酸酯聚合物负载软骨细胞修复同种异体喉软骨缺损

背景：软骨组织工程基础研究相当深入,但在耳鼻咽喉科实际应用研究颇少,探索组织工程技术简便实用的喉软骨修复方法是值得研究的课题。 目的：比较多孔海绵状聚羟基丁酸酯与聚羟基己酸酯共聚物生物材料负载软骨细胞体外培养形成的初期组织工程软骨组织与体内植入一定时期形成的较成熟组织工程软骨组织修复同种异体甲状软骨缺损的效果。 方法：收集体外培养第3代乳兔(3 d龄)软骨细胞,以多孔海绵状聚羟基丁酸酯与聚羟基己酸酯共聚物生物材料为细胞外基质,采用组织工程技术制备细胞-材料复合物,共同体外培养形成初级组织工程软骨组织后直接应用于成兔甲状软骨缺损的修复(实验组A,n=5)或将初级组织工程软骨组织体内植入一定时期形成较成熟组织工程软骨再应用于甲状软骨缺损的修复(实验组B,n=5)。设单纯聚羟基丁酸酯与聚羟基己酸酯共聚物材料修复组(对照A组,n=4)和单纯软骨细胞修复组(对照B组,n=4)作为对照。分别于术后4周(实验B组)和8周(实验A组、对照A组、对照B组)取材,对甲状软骨缺损修复效果进行大体和组织学评价。 结果与结论：两者大体支架形态基本一致,修复区与原有软骨均相续平坦,无凹陷及缺损。但实验A组存在界面无细胞区,修复区基质分泌不丰富;实验B组界面区有细胞生长,基质分泌良好。两者炎细胞浸润均不明显。对照组修复区凹陷,呈暗红色软组织充填,组织学及特殊染色检查未发现软骨样结构及其分泌的基质成分。结果表明在有免疫力的动物体内,初级组织工程软骨组织直接应用与体内植入后再应用均能有效修复同种异体甲状软骨缺损,无明显免疫反应;相同时期内,应用较成熟组织工程软骨组织修复效果优于应用初级组织工程软骨组织。然而,直接应用初级组织工程软骨组织可节省时间、成本、工作量及操作环节,避免二次皮下手术的痛苦,是比较实用的方法之一。     

多孔丝素蛋白/羟基磷灰石复合脂肪间充质干细胞修复兔关节软骨及软骨下骨缺损

背景：丝素蛋白/羟基磷灰石是细胞立体培养的良好支架,是临床常用的骨缺损修复材料,具有良好的生物相容性。脂肪干细胞具有向骨及软骨细胞分化的潜能,适合骨软骨缺损修复。 目的：观察转化生长因子β1和胰岛素样生长因子1联合成软骨诱导脂肪干细胞与丝素蛋白/羟基磷灰石复合后修复兔关节软骨及软骨下骨缺损的效果。 方法：取新西兰大白兔56只,2只用于传代培养脂肪间充质干细胞,以3×109 L-1浓度接种到丝素蛋白/羟基磷灰石。其余54只新西兰大白兔,在股骨髁间制备软骨缺损模型,随机分为细胞复合材料组、单纯材料组和空白对照组,细胞复合材料组植入复合脂肪间充质干细胞的丝素蛋白/羟基磷灰石;单纯材料组植入丝素蛋白/羟基磷灰石;空白对照组不作任何植入。从大体、影像学、组织学观察比较缺损的修复情况。 结果与结论：12周时大体观察、CT、磁共振和组织学检查细胞材料复合组软骨及软骨下骨缺损区完全被软骨组织修复,修复组织与周围软骨色泽相近,支架材料基本吸收,未见明显退变和白细胞浸润,所有标本均未见丝素蛋白残留。单纯材料组缺损区缩小、部分修复,且呈纤维软骨样修复。空白对照组缺损无明显修复。提示复合脂肪间充质干细胞的丝素蛋白/羟基磷灰石修复兔关节软骨及软骨下骨缺损能力优于单纯丝素蛋白/羟基磷灰石材料。丝素蛋白/羟基磷灰石复合脂肪间充质干细胞可形成透明软骨修复动物膝关节全层软骨缺损,重建关节的解剖结构和功能,可作为新型骨软骨组织工程支架。