Induction of cartilage integration by a chondrocyte/collagen-scaffold implant

The integration of implanted cartilage is a major challenge for the success of tissue engineering protocols. We hypothesize that in order for effective cartilage integration to take place, matrix-free chondrocytes must be induced to migrate between the two tissue surfaces. A chondrocyte/collagen-scaffold implant system was developed as a method of delivering dividing cells at the interface between two cartilage surfaces. Chondrocytes were isolated from bovine nasal septum and seeded onto both surfaces of a collagen membrane to create the chondrocyte/collagen-scaffold implant. A model of two cartilage discs and the chondrocyte/collagen-scaffold sandwiched in between was used to effect integration in vitro. The resulting tissue was analysed histologically and biomechanically. The cartilage–implant–cartilage sandwich appeared macroscopically as one continuous piece of tissue at the end of 40 day cultures. Histological analysis showed tissue continuum across the cartilage–scaffold interface. The integration was dependent on both cells and scaffold. Fluorescent labeling of implanted chondrocytes demonstrated that these cells invade the surrounding mature tissue and drive a remodelling of the extracellular matrix. Using cell-free scaffolds we also demonstrated that some chondrocytes migrated from the natural cartilage into the collagen scaffold. Quantification of integration levels using a histomorphometric repair index showed that the chondrocyte/collagen-scaffold implant achieved the highest repair index compared to controls, reflected functionally through increased tensile strength. In conclusion, cartilage integration can be achieved using a chondrocyte/collagen-scaffold implant that permits controlled delivery of chondrocytes to both host and graft mature cartilage tissues. This approach has the potential to be used therapeutically for implantation of engineered tissue.     

生物打印在肌肉骨骼界面重建中的应用

文题释义：生物打印：是一种能够在数字三维模型辅助下,根据增材制造原理定位装配生物材料或细胞单元,从而制备组织工程支架和组织器官等制品的一种新兴技术。 肌肉骨骼界面：是指肌肉骨骼系统中存在的一系列结构、功能和工程相似的部位,其通过肌肉和骨骼附着实现平滑连接,通常这些界面主要包括骨-肌腱、骨-韧带和骨-软骨等。其工作原理和潜在机制使它们成为组织的独特分支,其在细胞组分上显著不同,但在结构和功能上是一致的。 背景：肌肉骨骼损伤和退行性疾病的手术治疗常涉及肌肉骨骼界面的重建,而实现肌肉骨骼界面与周围宿主组织的生物整合的关键是制造具有精确结构和不同材料的替代物。生物打印技术获得的人工组织可与天然肌肉骨骼界面组织具有相似的物理结构和生物活性。 目的：介绍肌肉骨骼界面组织的结构和生物功能特性,以及生物打印技术在肌肉骨骼界面重建中的应用。 方法：由第一作者以“bioprinting, musculoskeletal interface,生物打印,肌肉骨骼界面”为关键词,检索2005至2019年期间PubMed、Web of Science、Springerlink、Medline、万方、CNKI数据库中的相关文献。初检文章201篇,筛选后对60篇文章进行分析。 结果与结论：理想的生物打印肌肉骨骼界面移植物必须结构上与原界面组织相对应,以维持体内多变的生物力学环境;其次,植入之后必须保持这些植入物的生物活性,以开始修复和替换缺陷区域的功能。生物打印技术的发展为解决肌肉骨骼界面的重建带来了希望,但其仍然存在许多挑战：仿生功能性界面结构机械性能的提高、多个仿生结构的整合、生物打印结构的血管化,以及对力学刺激在界面组织发育和再生中的作用缺乏深入的研究。对于未来界面组织工程的研究方向,可以预料的是将种子细胞、细胞因子和基因治疗,以及生物反应器纳入界面组织工程支架中的一大热点,为解决界面组织整合这一难题提供创新性的解决方案。 ORCID: 0000-0002-6668-5036(张君伟) 中国组织工程研究杂志出版内容重点：生物材料;骨生物材料; 口腔生物材料; 纳米材料; 缓释材料; 材料相容性;组织工程     

Evaluation of three-dimensional scaffolds prepared from poly(3-hydroxybutyrate-co-3-hydroxyhexanoate) for growth of allogeneic chondrocytes for cartilage repair in rabbits

Articular cartilage repair using tissue engineering approach generally requires the use of an appropriate scaffold architecture that can support the formation of cartilage tissue. In this investigation, the potential of three-dimensional scaffolds made of poly(3-hydroxybutyrate-co-3-hydroxyhexanoate) (PHBHHx) was evaluated in rabbit articular cartilage defect model. Engineered PHBHHx cartilage constructs inoculated in vitro with rabbit chondrocytes for 30 days were examined. Subsequently the constructs inoculated with chondrocytes for 10 days were selected for transplantation into rabbits. After 16 weeks of in vivo implantation, both the engineered cartilage constructs and the bare scaffolds were found to be filled the defects with white cartilaginous tissue, with the engineered constructs showing histologically good subchondral bone connection and better surrounding cartilage infusion. Owing to pre-seeded chondrocytes in the PHBHHx scaffolds, better surface integrality and more accumulation of extracellular matrix (ECM) including type II collagen and sGAG were achieved in the engineered cartilage constructs. The repaired tissues possessed an average compressive modulus of 1.58MPa. For comparison, the defects without repair treatments still showed defects with fibrous tissues. These results demonstrated that PHBHHx is a useful material for cartilage tissue engineering.     

Engineered osteochondral grafts using biphasic composite solid free-form fabricated scaffolds

Tissue engineering has provided an alternative to traditional strategies to repair cartilage damaged by injury or degenerative disease. A successful strategy to engineer osteochondral tissue will mimic the natural contour of the articulating surface, achieve native mechanical properties and functional load-bearing ability, and lead to integration with host cartilage and underlying subchondral bone. Image-based design (IBD) and solid free-form (SFF) fabrication can be used to generate scaffolds that are load bearing and match articular geometry. The objective of this study was to utilize materials and biological factors in an integrated approach to regenerate a multitissue interface. Biphasic composite scaffolds manufactured by IBD and SFF fabrication were used to simultaneously generate bone and cartilage in discrete regions and provide for the development of a stable interface between cartilage and subchondral bone. Poly-L-lactic acid/hydroxyapatite composite scaffolds were differentially seeded with fibroblasts transduced with an adenovirus expressing bone morphogenetic protein 7 (BMP-7) in the ceramic phase and fully differentiated chondrocytes in the polymeric phase. After subcutaneous implantation into mice, the biphasic scaffolds promoted the simultaneous growth of bone, cartilage, and a mineralized interface tissue. Within the ceramic phase, the pockets of tissue generated included blood vessels, marrow stroma, and adipose tissue. This combination of IBD and SFF-fabricated biphasic scaffolds with gene and cell therapy is a promising approach to regenerate osteochondral defects.     

Properties of cartilage engineered from elderly human chondrocytes for articular surface repair

Numerous studies on engineering cartilage utilizing chondrocytes from juvenile animal sources have been reported. However, there are many unknown aspects of engineering cartilage using human chondrocytes-especially from middle-aged or elderly adults-which are critical for clinical application of tissue engineering in the field of orthopedic surgery. The primary aim of this study was to engineer neocartilage tissue from 50-60-year-old human chondrocytes in comparison to engineered cartilage made from juvenile swine chondrocytes (JSCs). Articular chondrocytes from middle-aged, nonarthritic humans and juvenile swine were isolated and placed in culture for expansion. The chondrocytes (passage 1) were mixed in fibrin gel at 40-60×10(6) cells/mL until polymerization. Cells/nodule constructs and devitalized cartilage-cells/hydrogel-devitalized cartilage constructs (three-layered model) were implanted into subcutaneous pockets of nude mice for 12, 18, and 24 weeks. The specimens were evaluated histologically, biochemically, and biomechanically. This allowed for direct comparison of the cartilage engineered from human versus swine cells. Histological analysis demonstrated that samples engineered utilizing chondrocytes from middle-aged adults accumulated basophilic, sulfated glycosaminoglycans (sGAG), and abundant type II collagen around the cells in a manner similar to that seen in samples engineered using JSCs at all time points. Biochemical analysis revealed that samples made with human cells had about 40%-60% of the amount hydroxyproline of native human cartilage, a trend parallel to that observed in the specimens made with swine chondrocytes. The amount of sGAG in the human chondrocyte specimens was about one-and-a-half times the amount in native human cartilage, whereas the amount in the samples made with swine chondrocytes was always less than native cartilage. The biomechanical analysis revealed that the stiffness and tensile of samples made with human cells were in a pattern similar to that seen with swine chondrocytes. This study demonstrates that chondrogenesis using articular chondrocytes from middle-aged adults can be achieved in a predictable and reliable manner similar to that shown in studies using cells from juvenile animals and can form the basis of engineering cartilage with degradable scaffolds in this patient population.     

A novel 3D histotypic cartilage construct engineered by supercritical carbon dioxide decellularized porcine nasal cartilage graft and chondrocytes exhibited chondrogenic capability in vitro

Augmentative and reconstructive rhinoplasty surgical procedures use autologous tissue grafts or synthetic grafts to repair the nasal defect and aesthetic reconstruction. Donor site trauma and morbidity are common in autologous grafts. The desperate need for the production of grafted 3D cartilage tissues as rhinoplasty grafts without the adverse effect is the need of the hour. In the present study, we developed a bioactive 3D histotypic construct engineered with the various ratio of adipose-derived stem cells (ADSC) and chondrocytes together with decellularized porcine nasal cartilage graft (dPNCG). We decellularized porcine nasal cartilage using supercritical carbon dioxide (SCCO2) extraction technology. dPNCG was characterized by H&E, DAPI, alcian blue staining, scanning electron microscopy and residual DNA content, which demonstrated complete decellularization. 3D histotypic constructs were engineered using dPNCG, rat ADSC and chondrocytes with different percentage of cells and cultured for 21 days. dPNCG together with 100% chondrocytes produced a solid mass of 3D histotypic cartilage with significant production of glycosaminoglycans. H&E and alcian blue staining showed an intact mass, with cartilage granules bound to one another by extracellular matrix and proteoglycan, to form a 3D structure. Besides, the expression of chondrogenic markers, type II collagen, aggrecan and SOX-9 were elevated indicating chondrocytes cultured on dPNCG substrate facilitates the synthesis of type II collagen along with extracellular matrix to produce 3D histotypic cartilage. To conclude, dPNCG is an excellent substrate scaffold that might offer a suitable environment for chondrocytes to produce 3D histotypic cartilage. This engineered 3D construct might serve as a promising future candidate for cartilage tissue engineering in rhinoplasty.     

3D bioprinting of neural stem cell-laden thermoresponsive biodegradable polyurethane hydrogel and potential in central nervous system repair

The 3D bioprinting technology serves as a powerful tool for building tissue in the field of tissue engineering. Traditional 3D printing methods involve the use of heat, toxic organic solvents, or toxic photoinitiators for fabrication of synthetic scaffolds. In this study, two thermoresponsive water-based biodegradable polyurethane dispersions (PU1 and PU2) were synthesized which may form gel near 37 °C without any crosslinker. The stiffness of the hydrogel could be easily fine-tuned by the solid content of the dispersion. Neural stem cells (NSCs) were embedded into the polyurethane dispersions before gelation. The dispersions containing NSCs were subsequently printed and maintained at 37 °C. The NSCs in 25–30% PU2 hydrogels (∼680–2400 Pa) had excellent proliferation and differentiation but not in 25–30% PU1 hydrogels. Moreover, NSC-laden 25–30% PU2 hydrogels injected into the zebrafish embryo neural injury model could rescue the function of impaired nervous system. However, NSC-laden 25–30% PU1 hydrogels only showed a minor repair effect in the zebrafish model. In addition, the function of adult zebrafish with traumatic brain injury was rescued after implantation of the 3D-printed NSC-laden 25% PU2 constructs. Therefore, the newly developed 3D bioprinting technique involving NSCs embedded in the thermoresponsive biodegradable polyurethane ink offers new possibilities for future applications of 3D bioprinting in neural tissue engineering.     

Cell-based tissue-engineered allogeneic implant for cartilage repair

The potential for using of allogeneic cartilage chips, transplanted in a biologic polymer with articular chondrocytes, as a tool for articular cartilage repair was studied. Small lyophilized articular cartilage chips were mixed with a cell/fibrinogen solution and thrombin to obtain implantable constructs made of fibrin glue, chondrocytes, and cartilage chips. Specimens were implanted in the subcutaneous tissue on the backs of nude mice (experimental group A). Three groups of controls (groups B, C, and D) were also prepared. Group B consisted of fibrin glue and cartilage chips without chondrocytes. Group C consisted of fibrin glue and chondrocytes without cartilage chips, and group D was composed solely of fibrin glue. All samples were carefully weighed before implantation in the mice. The constructs were harvested from the animals at 6, 9, and 12 weeks, examined grossly, and weighed. The samples were then processed and stained with hematoxylin and eosin for histological examination. Gross evaluation and weight analysis of the constructs at the time of retrieval showed retention of the original mass in the samples made of fibrin glue, chondrocytes, and cartilage chips (group A) and demonstrated a cartilaginous consistency upon probing. Specimens from constructs of fibrin glue and cartilage chips without chondrocytes (control group B) retained most of their volume, but were statistically lighter than specimens from group A and were much softer and more pliable than those in group A. Samples of specimens from constructs of fibrin glue and chondrocytes (groups C) and fibrin glue alone (group D) both showed a substantial reduction of their original masses over the experimental time periods when compared to the samples in groups A and B, although specimens from group C demonstrated new cartilage matrix formation. Histological analysis of specimens in experimental group A demonstrated the presence of cartilage chips surrounded by newly formed cartilaginous matrix, while specimens of control group B showed only fibrotic tissue surrounding the devitalized cartilage pieces. Cartilaginous matrix was also observed in control group C, in which cartilage chips were absent, whereas only fibrin glue debris was observed in control group D. This study demonstrated that a composite of fibrin glue and devitalized cartilage can serve as a scaffold for chondrocyte transplantation, preserve the original phenotype of the chondrocytes, and maintain the original mass of the implant. This may represent a valid option for addressing the problem of articular cartilage repair.     

Engineering alginate as bioink for bioprinting

Recent advances in three-dimensional (3-D) printing offer an excellent opportunity to address critical challenges faced by current tissue engineering approaches. Alginate hydrogels have been used extensively as bioinks for 3-D bioprinting. However, most previous research has focused on native alginates with limited degradation. The application of oxidized alginates with controlled degradation in bioprinting has not been explored. Here, a collection of 30 different alginate hydrogels with varied oxidation percentages and concentrations was prepared to develop a bioink platform that can be applied to a multitude of tissue engineering applications. The authors systematically investigated the effects of two key material properties (i.e. viscosity and density) of alginate solutions on their printabilities to identify a suitable range of material properties of alginates to be applied to bioprinting. Further, four alginate solutions with varied biodegradability were printed with human adipose-derived stem cells (hADSCs) into lattice-structured, cell-laden hydrogels with high accuracy. Notably, these alginate-based bioinks were shown to be capable of modulating proliferation and spreading of hADSCs without affecting the structure integrity of the lattice structures (except the highly degradable one) after 8 days in culture. This research lays a foundation for the development of alginate-based bioink for tissue-specific tissue engineering applications.     

Cartilage engineering using chondrocyte cell sheets and its application in reconstruction of microtia

The imperfections of scaffold materials have hindered the clinical application of cartilage tissue engineering. The recently developed cell-sheet technique is adopted to engineer tissues without scaffold materials, thus is considered being potentially able to overcome the problems concerning the scaffold imperfections. This study constructed monolayer and bilayer chondrocyte cell sheets and harvested the sheets with cell scraper instead of temperature-responsive culture dishes. The properties of the cultured chondrocyte cell sheets and the feasibility of cartilage engineering using the chondrocyte cell sheets was further investigated via in vitro and in vivo study. Primary extracellular matrix (ECM) formation and type II collagen expression was detected in the cell sheets during in vitro culture. After implanted into nude mice for 8 weeks, mature cartilage discs were harvested. The morphology of newly formed cartilage was similar in the constructs originated from monolayer and bilayer chondrocyte cell sheet. The chondrocytes were located within evenly distributed ovoid lacunae. Robust ECM formation and intense expression of type II collagen was observed surrounding the evenly distributed chondrocytes in the neocartilages. Biochemical analysis showed that the DNA contents of the neocartilages were higher than native human costal cartilage; while the contents of the main component of ECM, glycosaminoglycan and hydroxyproline, were similar to native human costal cartilage. In conclusion, the chondrocyte cell sheet constructed using the simple and low-cost technique is basically the same with the cell sheet cultured and harvested in temperature-responsive culture dishes, and can be used for cartilage tissue engineering.     

Can microcarrier-expanded chondrocytes synthesize cartilaginous tissue in vitro?

Tissue engineering is a promising approach for articular cartilage repair; however, it is challenging to produce adequate amounts of tissue in vitro from the limited number of cells that can be extracted from an individual. Relatively few cell expansion methods exist without the problems of de-differentiation and/or loss of potency. Recently, however, several studies have noted the benefits of three-dimensional (3D) over monolayer expansion, but the ability of 3D expanded chondrocytes to synthesize cartilaginous tissue constructs has not been demonstrated. Thus, the purpose of this study was to compare the properties of engineered cartilage constructs from expanded cells (monolayer and 3D microcarriers) to those developed from primary chondrocytes. Isolated bovine chondrocytes were grown for 3 weeks in either monolayer (T-Flasks) or 3D microcarrier (Cytodex 3) expansion culture. Expanded and isolated primary cells were then seeded in high density culture on Millicell? filters for 4 weeks to evaluate the ability to synthesize cartilaginous tissue. While microcarrier expansion was twice as effective as monolayer expansion (microcarrier: 110-fold increase, monolayer: 52-fold increase), the expanded cells (monolayer and 3D microcarrier) were not effectively able to synthesize cartilaginous tissue in vitro. Tissues developed from primary cells were substantially thicker and accumulated significantly more extracellular matrix (proteoglycan content: 156%-292% increase; collagen content: 70%-191% increase). These results were attributed to phenotypic changes experienced during the expansion phase. Monolayer expanded chondrocytes lost their native morphology within 1 week, whereas microcarrier-expanded cells were spreading by 3 weeks of expansion. While the use of 3D microcarriers can lead to large cellular yields, preservation of chondrogenic phenotype during expansion is required in order to synthesize cartilaginous tissue.     

Evaluation of multiphase implants for repair of focal osteochondral defects in goats

The use of biodegradable scaffolds for articular cartilage repair has been investigated by numerous researchers. The objective of this screening study was to examine how the mechanical and physical properties of four multiphase implants can affect the cartilage healing response. Multiphase implant prototypes were prepared using poly(D,L)lactide-co-glycolide as the base material. PGA fibers (FR), 45S5 Bioglass (BG) and medical grade calcium sulfate (MGCS) were used as additives to vary stiffness and chemical properties. Osteochondral defects (3 mm dia. and 4 mm in depth) were created bilaterally in the medial femoral condyle (high-weight bearing) and the distal medial portion of the patellar groove (low-weight bearing) of 16 Spanish goats. Half of the implants were loaded with autologous costochondral chondrocytes. Defect sites (total n = 64, 4 sites/treatment) were randomly treated and allowed to heal for 16 weeks, fully weight bearing. At euthanasia, gross evaluations and biomechanical testing were conducted. Histological sections of the defect sites were stained with H and E, Safranin O/Fast Green or processed to analyze collagen architecture. Sections were semi-quantitatively scored for repair tissue structure. Qualitative evaluations showed that all groups had a high percentage of hyaline cartilage and good bony restoration, with new tissue integrating well with the native cartilage. Gross and histology scoring indicated a significantly higher score for defect healing in the condyle than in the patellar groove, but no difference in healing for implant types or addition/omission of cells was found. This investigation demonstrates that focal, osteochondral defects in caprine distal femurs treated with various implant constructs were repaired with hyaline-like cartilage and good underlying bone. The multiphase implants show potential for treatment of osteochondral defects and long-term studies need to be undertaken to confirm the longevity of the regenerated tissue.     

Articular cartilage repair in rabbits by using suspensions of allogenic chondrocytes in alginate

The feasibility of allogenic implants of chondrocytes in alginate gels was tested for the reconstruction in vivo of artificially full-thickness-damaged articular rabbit cartilage. The suspensions of chondrocytes in alginate were gelled by the addition of calcium chloride solution directly into the defects giving in situ a construct perfectly inserted and adherent to the subchondral bone and to the walls of intact cartilage. The tissue repair was controlled at 1, 2, 4 and 6 months after the implant by NMR microscopy, synchrotron radiation induced X-ray emission to map the sulfur of glycosaminoglycans and by histochemistry. Practically a complete repair of the defect was observed 4-6 months from the implant of the chondrocytes with the recovery of a normal tissue structure. Controls in which Ca-alginate alone was implanted developed only a fibrous cartilage.     

环境、材料、安全、可控：组织工程技术修复关节软骨的症结*

背景：传统的软骨缺损的修复方法都有其局限性,组织工程技术的出现从根本上改变了“以创伤修复创伤”的传统治疗模式。 目的：总结分析目前组织工程技术修复关节软骨的研究进展。 方法：由第一作者检索1990年至2011年 PubMed数据及中国知网数据库有关应用组织工程技术修复关节软骨方面的文献。共检索中文187 篇,英文211 篇,最终保留49篇进入结果分析。 结果与结论：软骨组织工程的主要方法就是应用工程学和生命科学原理,在体外分离、培养、扩增所需要的种子细胞,然后将之种植于合适的生物支架材料上,将细胞支架复合体植入体内组织缺损部位,并加入一定的诱导条件,逐渐形成新的有功能的软骨组织。文章在种子细胞的选择方面重点叙述了自体软骨细胞、异体软骨细胞、胚胎干细胞、骨髓间充质干细胞的研究进展;在细胞诱导及条件培养方面重点叙述了细胞因子、细胞条件培养、转基因技术的研究进展;并对生物支架材料的选择和研究进行了相关叙述。找到最理想的种子细胞,合理联合应用细胞因子,更加真实的模拟细胞生存的微环境,基因工程安全、高效、可控转染,构建理想的支架材料,将是今后组织工程研究的重点和热点。     

In vivo cultivation of human articular chondrocytes in a nude mouse-based contained defect organ culture model

The nude mouse model is an established method to cultivate and investigate tissue engineered cartilage analogues under in vivo conditions. One limitation of this common approach is the lack of appropriate surrounding articular tissues. Thus the bonding capacity of cartilage repair tissue cannot be evaluated. Widely applied surgical techniques in cartilage repair such as conventional and three-dimensional autologous chondrocyte implantation (ACI) based on a collagen gel matrix cannot be included into nude mouse studies, since their application require a contained defect. The aim of this study is to apply an organ culture defect model for the in vivo cultivation of different cell-matrix-constructs.Cartilage defects were created on osteochondral specimens which had been harvested from 10 human knee joints during total knee replacement. Autologous chondrocytes were isolated from the cartilage samples and cultivated in monolayer until passage 2. On each osteochondral block defects were treated either by conventional ACI or a collagen gel seeded with autologous chondrocytes, including a defect left empty as a control. The samples were implanted into the subcutaneous pouches of nude mice and cultivated for six weeks. After retrieval, the specimens were examined histologically, immunohistochemically and by cell morphology quantification.In both, ACI and collagen gel based defect treatment, a repair tissue was formed, which filled the defect and bonded to the adjacent tissues. The repair tissue was immature with low production of collagen type II. In both groups redifferentiation of chondrocytes remained incomplete. Different appearances of interface zones between the repair tissue and the adjacent cartilage were found.The presented contained defect organ culture model offers the possibility to directly compare different types of clinically applied biologic cartilage repair techniques using human articular tissues in a nude mouse model.     

An analysis of the integration between articular cartilage and nondegradable hydrogel using magnetic resonance imaging

A hydrogel is a highly hydrated polymer gel suitable for use as a scaffold for tissue engineering. One important application is to the repair of cartilage defects due to injury or osteoarthritis. Integration of the hydrogel with surrounding tissue is critical for the long-term functionality of the implant; however direct visualization of integration is difficult and invasive. Accordingly, we used MRI to noninvasively investigate the integration of hydrogel in cartilage. Two integration methods were assessed: (1) cartilage-initiated and (2) chemical, using chondroitin sulphate-methacrylate-aldehyde (CS-MA-ald) as an adhesive. These were compared to a control group, that is, standard, nonintegrated hydrogel photopolymerization. Spatial variation of the transverse relaxation time, T(2), across the transition region was used to determine the effectiveness of integration. In the CS-MA-ald group only, two interfaces were found. This provides evidence of an intermediate adhesive layer between hydrogel and cartilage. Second, the thickness of the transition region between hydrogel to cartilage in the CS-MA-ald group was 1.32 mm as compared to 1.20 mm and 1.17 mm in the tissue-initiated and nonintegrated groups, respectively. We interpret this as a more gradual transition region of hydrogel to cartilage and hence a greater degree of integration when an adhesive layer is present.     

自体脂肪间充质干细胞复合人脐带Wharton胶支架修复兔膝关节软骨缺损****◇

背景：脐带Wharton胶富含透明质酸,糖胺多糖及胶原等,成分与天然软骨细胞外基质类似,因此由人脐带提取的Wharton胶很可能是一种较为理想的软骨组织工程支架材料。 目的：评价自体脂肪间充质干细胞复合人脐带Wharton胶支架修复兔膝关节软骨缺损的效果。 方法：将终浓度为1010 L -1、成软骨方向诱导后的兔自体脂肪间充质干细胞与人脐带Wharton胶支架复合,继续培养1周构建组织工程软骨,对兔膝关节全层软骨缺损进行修复(实验组),并与单纯支架修复的对照组及空白组进行比较。术后3个月对修复组织行大体观察、组织学检测、糖胺多糖、总胶原定量检测及生物力学测定。 结果与结论：实验组的缺损多为透明软骨修复,对照组以纤维组织修复为主,空白组无明显组织修复。提示脂肪间充质干细胞作为软骨组织工程种子细胞具有可行性;实验构建的组织工程软骨能有效的修复关节软骨缺损,人脐带Wharton胶可作为软骨组织工程良好的支架材料。     

Tissue engineering-based cartilage repair with allogenous chondrocytes and gelatin-chondroitin-hyaluronan tri-copolymer scaffold: a porcine model assessed at 18, 24, and 36 weeks

We previously showed that cartilage tissue can be engineered in vitro with porcine chondrocytes and gelatin/chondoitin-6-sulfate/hyaluronan tri-copolymer which mimic natural cartilage matrix for use as a scaffold. In this animal study, 15 miniature pigs were used in a randomized control study to compare tissue engineering with allogenous chondrocytes, autogenous osteochondral (OC) transplantation, and spontaneous repair for OC articular defects. In another study, 6 pigs were used as external controls in which full thickness (FT) and OC defects were either allowed to heal spontaneously or were filled with scaffold alone. After exclusion of cases with infection and secondary arthritis, the best results were obtained with autogenous OC transplantation, except that integration into host cartilage was poor. The results for the tissue engineering-treated group were satisfactory, the repair tissue being hyaline cartilage and/or fibrocartilage. Spontaneous healing and filling with scaffold alone did not result in good repair. With OC defects, the subchondral bone plate was not restored by cartilage tissue engineering. These results show that tri-copolymer can be used in in vivo cartilage tissue engineering for the treatment of FT articular defects.     

Regenerated silk fibroin scaffold and infrapatellar adipose stromal vascular fraction as feeder-layer: a new product for cartilage advanced therapy

Articular cartilage has limited repair and regeneration potential, and the scarcity of treatment modalities has motivated attempts to engineer cartilage tissue constructs. The use of chondrocytes in cartilage tissue engineering has been restricted by the limited availability of these cells, their intrinsic tendency to lose their phenotype during the expansion, as well as the difficulties during the first cell adhesion to the scaffold. Aim of this work was to evaluate the intra-articular adipose stromal vascular fraction attachment on silk fibroin scaffold to promote chondrocytes adhesion and proliferation. Physicochemical characterization has demonstrated that three-dimensionally organized silk fibroin scaffold is an ideal biopolymer for cartilage tissue engineering; it allows cell attachment, scaffold colonization, and physically cell holding in the area that must be repaired; the use of adipose-derived stem cells is a promising strategy to promote adhesion and proliferation of chondrocytes to the scaffold as an autologous human feeder layer.