Differentiation Capacity of Human Chondrocytes Embedded in Alginate Matrix

Healing capacity of cartilage is low. Thus, cartilage defects do not regenerate as hyaline but mostly as fibrous cartilage which is a major drawback since this tissue is not well adapted to the mechanical loading within the joint. During in vitro cultivation in monolayers, chondrocytes proliferate and de-differentiate to fibroblasts. In three-dimensional cell cultures, de-differentiated chondrocytes could re-differentiate toward the chondrogenic lineage and re-express the chondrogenic phenotype. The objective of this study was to characterize the mesenchymal stem cell (MSC) potential of human chondrocytes isolated from articular cartilage. Furthermore, the differentiation capacity of human chondrocytes in three-dimensional cell cultures was analyzed to target differentiation direction into hyaline cartilage. After isolation and cultivation of chondrogenic cells, the expression of the MSC-associated markers: cluster of differentiation (CD)166, CD44, CD105, and CD29 was performed by flow cytometry. The differentiation capacity of human chondrocytes was analyzed in alginate matrix cultured in Dulbecco’s modified eagle medium with (chondrogenic stimulation) and without (control) chondrogenic growth factors. Additionally, the expression of collagen type II, aggrecan, and glycosaminoglycans was determined. Cultivated chondrocytes showed an enhanced expression of the MSC-associated markers with increasing passages. After chondrogenic stimulation in alginate matrix, the chondrocytes revealed a significant increase of cell number compared with unstimulated cells. Further, a higher synthesis rate of glycosaminoglycans and a positive collagen type II and aggrecan immunostaining was detected in stimulated alginate beads. Human chondrocytes showed plasticity whilst cells were encapsulated in alginate and stimulated by growth factors. Stimulated cells demonstrated characteristics of chondrogenic re-differentiation due to collagen type II and aggrecan synthesis.     

Differentiation capacity of human chondrocytes embedded in alginate matrix

Healing capacity of cartilage is low. Thus, cartilage defects do not regenerate as hyaline but mostly as fibrous cartilage which is a major drawback since this tissue is not well adapted to the mechanical loading within the joint. During in vitro cultivation in monolayers, chondrocytes proliferate and de-differentiate to fibroblasts. In three-dimensional cell cultures, de-differentiated chondrocytes could re-differentiate toward the chondrogenic lineage and re-express the chondrogenic phenotype. The objective of this study was to characterize the mesenchymal stem cell (MSC) potential of human chondrocytes isolated from articular cartilage. Furthermore, the differentiation capacity of human chondrocytes in three-dimensional cell cultures was analyzed to target differentiation direction into hyaline cartilage. After isolation and cultivation of chondrogenic cells, the expression of the MSC-associated markers: cluster of differentiation (CD)166, CD44, CD105, and CD29 was performed by flow cytometry. The differentiation capacity of human chondrocytes was analyzed in alginate matrix cultured in Dulbecco?s modified eagle medium with (chondrogenic stimulation) and without (control) chondrogenic growth factors. Additionally, the expression of collagen type II, aggrecan, and glycosaminoglycans was determined. Cultivated chondrocytes showed an enhanced expression of the MSC-associated markers with increasing passages. After chondrogenic stimulation in alginate matrix, the chondrocytes revealed a significant increase of cell number compared with unstimulated cells. Further, a higher synthesis rate of glycosaminoglycans and a positive collagen type II and aggrecan immunostaining was detected in stimulated alginate beads. Human chondrocytes showed plasticity whilst cells were encapsulated in alginate and stimulated by growth factors. Stimulated cells demonstrated characteristics of chondrogenic re-differentiation due to collagen type II and aggrecan synthesis.     

骨髓间充质干细胞复合多肽凝胶及成软骨生成因子修复兔关节软骨缺损

背景：多肽水凝胶因为其具有良好的可塑型性,能够与损伤部位很好的无缝隙结合,所以采用该材料作为支架是骨、软骨组织工程中一种可行的探索。 目的：骨髓间充质干细胞联合新型可注射多肽凝胶及成软骨生成因子修复兔关节软骨缺损,观察其修复效果。 方法：首先分离培养兔骨髓间充质干细胞,兔左侧膝关节处制备直径5 mm,深3 mm的全层骨-软骨缺损模型;右侧造模后空置作为对照。实验分为3组,单纯自组装多肽凝胶移植组,自组装多肽凝胶+成软骨因子组和自组装多肽凝胶+成软骨因子+骨髓间充质干细胞组。采用的成软骨因子包括转化生长因子β1,地塞米松和胰岛素样生长因子1,三者混合后加入到自组装多肽凝胶或骨髓间充质干细胞中。于处理后12周时处死动物行大体及组织学观察、X射线摄片、免疫组织化学法进行组织学评分评估修复情况。 结果与结论：单纯自组装多肽凝胶移植在12周后显示出非常好的修复效果,可见番红O染色,Ⅱ型胶原蛋白免疫组织化学染色强度以及组织学评分明显高于其他组(P < 0.05)。自组装多肽凝胶+成软骨因子组修复效果较好,与自组装多肽凝胶组相似,但其修复区域蛋白聚糖表达比对照组明显升高(P < 0.01)。自组装多肽凝胶+成软骨因子+骨髓间充质干细胞组修复效果不佳,12周未能完全修复缺损区域,与单纯自组装多肽凝胶组比较骨赘的形成有所增加。结果表明,单纯自组装多肽凝胶能够在原位修复骨软骨缺损并促进软骨修复,提示以自组装多肽凝胶支架移植有望提高目前修复软骨缺损的效果。中国组织工程研究杂志出版内容重点：干细胞;骨髓干细胞;造血干细胞;脂肪干细胞;肿瘤干细胞;胚胎干细胞;脐带脐血干细胞;干细胞诱导;干细胞分化;组织工程全文链接：     

Equal Cartilage Repair Response Between Autologous Chondrocytes in a Collagen Scaffold and Minced Cartilage Under a Collagen Scaffold: An in Vivo Study in Goats

Cell-free methods for cartilage tissue repair have recently gained increased focus. One method to supply a chondrogenic cell source is to apply freshly harvested cartilage tissue to the defects area and to retain the tissue for cell outgrowth. The present study aims to investigate the cartilage repair response of autologous cartilage chips or chondrocytes in combination with a collagen membrane in a goat femoral condyle full thickness cartilage defect model. Fully 16 defects in 8 adult goats were used for the study. A total of 6 mm full-thickness cartilage defects in the femoral condyles were randomized to collagen membrane matrix scaffold with chondrocytes and minced cartilage placed under collagen membrane scaffold. Animals were followed for 4 months. No difference was found in O'Driscoll and Pinada histology scores, tissue filling (35%), or repair tissue stiffness between the two groups. This animal study demonstrated no difference in cartilage repair between the two different techniques. The general tissue regeneration was limited probably due to the early time point of investigation and the challenging mechanical environment.     

Cell sources for the regeneration of articular cartilage: the past,the horizon and the future

Avascular, aneural articular cartilage has a low capacity for self‐repair and as a consequence is highly susceptible to degradative diseases such as osteoarthritis. Thus the development of cell‐based therapies that repair focal defects in otherwise healthy articular cartilage is an important research target, aiming both to delay the onset of degradative diseases and to decrease the need for joint replacement surgery. This review will discuss the cell sources which are currently being investigated for the generation of chondrogenic cells. Autologous chondrocyte implantation using chondrocytes expanded ex vivo was the first chondrogenic cellular therapy to be used clinically. However, limitations in expansion potential have led to the investigation of adult mesenchymal stem cells as an alternative cell source and these therapies are beginning to enter clinical trials. The chondrogenic potential of human embryonic stem cells will also be discussed as a developmentally relevant cell source, which has the potential to generate chondrocytes with phenotype closer to that of articular cartilage. The clinical application of these chondrogenic cells is much further away as protocols and tissue engineering strategies require additional optimization. The efficacy of these cell types in the regeneration of articular cartilage tissue that is capable of withstanding biomechanical loading will be evaluated according to the developing regulatory framework to determine the most appropriate cellular therapy for adoption across an expanding patient population.     

An in vitro study of collagen hydrogel to induce the chondrogenic differentiation of mesenchymal stem cells

It is controversial whether a biomaterial itself, rather than addition of any exogenous growth factor, could induce mesenchymal stem cells (MSCs) to differentiate into chondrogenic lineage, further to regenerate cartilage. Previous studies have shown that collagen-based hydrogel could induce MSCs to differentiate into chondrocytes in vivo but the in vitro studies only have a few reports. The evidence that biomaterials could induce chondrogenesis is not adequate. In this study, we tried to address whether type I collagen hydrogel has chondro-inductive capability in vitro and how this scaffold induces MSCs to generate cartilage tissue without exogenous growth factors in the culture medium. We encapsulated neonatal rabbit bone marrow mesenchymal stem cells (BMSCs) in type I collagen hydrogel homogeneously or implanted cell aggregates in hydrogel, and cultured them in nonchondrogenic inductive media. After at least 28 days culture, cells in the homogeneous group were tending to chondrogenic differentiation while cell density was high, and cells in the aggregate group have almost gone through chondrogenesis and formed neo-cartilage tissue with abundant specific extracellular matrix (ECM) deposition. These results indicate collagen hydrogel has inherent inductivity for the chondrogenic differentiation of BMSCs, and the optimum specification and tissue formation were accompanied with local high cell density. This research suggests a feasible strategy to induce the chondro differentiation of BMSCs independent of exogenous growth factors, which may greatly contribute to clinical cartilage regeneration. ? 2012 Wiley Periodicals, Inc. J Biomed Mater Res Part A 100A: 2717-2725, 2012.     

Morphology and function of ovine articular cartilage chondrocytes in 3-d hydrogel culture

Different cell- and biomaterial-based tissue engineering techniques are under investigation to restore damaged tissue. Strategies that use chondrogenic cells or tissues in combination with bioresorbable delivery materials are considered to be suitable to regenerate bio-artificial cartilage. Three-dimensional (3-D) cell embedding techniques can provide anchorage-independent cell growth and homogenous spatial cell arrangement, which play a key role in the maintenance of the characteristic phenotype and thus the formation of differentiated tissue. We developed a new injectable high water content (90%) hydrogel formulation with 5% sodium alginic acid and 5% gelatin as a temporary supportive intercellular matrix for 3-D cell culture. The objective was to determine whether the in vitro hydrogel culture of chondrocytes could preserve hyaline characteristics and thus could provide cartilage regeneration in vitro. Chondrocytes harvested from knee joints of skeletally mature sheep were cultured 3-D in hydrogel (7 x 10(6) cells/ml, 2.8-mul beads) for up to 10 weeks. Cell morphology and viability were evaluated with light microscopy, and proliferative activity was assessed with antibromodeoxyuridine immunofluorescence. Expression of collagens type I (COL1) and II (COL2), cartilage proteoglycans (PG) and hyaluronan synthases (HAS) were studied immunohistochemically. We observed that up to 36% of chondrocytes proliferated, while almost 100% presented a differentiated spheroidal phenotype. After an initial decrease at 2 weeks, cell density recovered to 85% of the initial absolute value at 10 weeks. Expression of hyaline matrix molecules resembled the in vivo pattern with increasing spatial deposition of PG and COL2. The proportion of PG-positive cells increased from initially 13 to 53% after 10 weeks, in contrast to consistently 100% COL2-positive cells. We conclude that 3-D hydrogel culture, even without mechanical stimulation or growth factor application, can keep chondrocytes in a differentiated state and provides a chondrogenic cell environment for in vitro cartilage regeneration for at least 10 weeks. Moreover, this hydrogel appears to be a suitable cell delivery material for subsequent in vivo implantation.     

Chondrogenic Differentiation of Amniotic Fluid Stem Cells and Their Potential for Regenerative Therapy

Chronic articular cartilage defects are the most common disabling conditions of humans in the western world. The incidence for cartilage defects is increasing with age and the most prominent risk factors are overweight and sports associated overloading. Damage of articular cartilage frequently leads to osteoarthritis due to the aneural and avascular nature of articular cartilage, which impairs regeneration and repair. Hence, patients affected by cartilage defects will benefit from a cell-based transplantation strategy. Autologous chondrocytes, mesenchymal stem cells and embryonic stem cells are suitable donor cells for regeneration approaches and most recently the discovery of amniotic fluid stem cells has opened a plethora of new therapeutic options. It is the aim of this review to summarize recent advances in the use of amniotic fluid stem cells as novel cell sources for the treatment of articular cartilage defects. Molecular aspects of articular cartilage formation as well as degeneration are summarized and the role of growth factor triggered signaling pathways, scaffolds, hypoxia and autophagy during the process of chondrogenic differentiation are discussed.     

Species variability in the differentiation potential of in vitro-expanded articular chondrocytes restricts predictive studies on cartilage repair using animal models

Autologous chondrocyte implantation is currently applied in clinics as an innovative tool for articular cartilage repair. Animal models have been and still are being used to validate and further improve the technique. However, in various species, the outcome varies from hyaline-like cartilage to fibrocartilage. This may be due partly to the spontaneous dedifferentiation of chondrocytes once cultured in vitro. Here we assessed whether the extent of dedifferentiation varies between species and we hypothesized that the level of chondrocyte phenotype stability during expansion may contribute to the maintenance of their chondrogenic commitment and redifferentiation potential. Condyle chondrocytes were harvested from sheep, dog, and human, and expanded for 1, 6, or 12 cell duplications. At each interval, cell phenotype was monitored (morphology and biosynthesis of cartilage markers) and redifferentiation was assessed by an in vitro assay of chondrogenesis in micromass pellet and an in vivo assay of ectopic cartilage formation in immunodeficient mice. Results indicate that, during culture, the sheep chondrocyte phenotype is maintained better than that of human chondrocytes, which in turn dedifferentiate to a lesser extent than dog chondrocytes Accordingly, after expansion, sheep chondrocytes spontaneously reform hyaline-like cartilage; human chondrocytes redifferentiate only under stimulation with chondrogenic inducers whereas, after a few passages, dog chondrocytes lose any capacity to redifferentiate regardless of the presence of inducers. Thus, conditions allowing cartilage formation in one species are not necessarily transposable to other species. Therefore, results with animal models should be cautiously applied to humans. In addition, for tissue-engineering purposes, the number of cell duplications must be, for each species, carefully monitored to remain in the range of amplification allowing redifferentiation and chondrogenesis.     

Three-dimensional polycaprolactone scaffold-conjugated bone morphogenetic protein-2 promotes cartilage regeneration from primary chondrocytes in vitro and in vivo without accelerated endochondral ossification

As articular cartilage is avascular, and mature chondrocytes do not proliferate, cartilage lesions have a limited capacity for regeneration after severe damage. The treatment of such damage has been challenging due to the limited availability of autologous healthy cartilage and lengthy and expensive cell isolation and expansion procedures. Hence, the use of bone morphogenetic protein-2 (BMP-2), a potent regulator of chondrogenic expression, has received considerable attention in cartilage and osteochondral tissue engineering. However, the exact role of BMP-2 in cartilage repair has been postulated to promote both cartilage formation and subsequent cartilage degradation through hypertrophy and endochondral ossification. Furthermore, it is likely that the manner in which BMP-2 is presented to chondrocytes will influence the physiologic pathway (repair vs. degeneration). This study investigates the relative influence of BMP-2 on cartilage matrix and potential subsequent bone matrix production using primary chondrocytes seeded on designed 3D polycaprolactone (PCL) scaffolds with chemically conjugated BMP-2. The results show that chemically conjugated BMP-2 PCL scaffolds can promote significantly greater cartilage regeneration from seeded chondrocytes both in vitro and in vivo compared with untreated scaffolds. Furthermore, our results demonstrate that the conjugated BMP-2 does not particularly accelerate endochondral ossification even in a readily permissible and highly vascular in vivo environment compared with untreated PCL scaffolds. This study not only reveals the potential use of the BMP-2 conjugation delivery method for enhanced cartilage tissue formation but also gives new insights for the effects of conjugated BMP-2 on cartilage regeneration and osteochondral ossification.     

Mesenchymal stem cell sheet encapsulated cartilage debris provides great potential for cartilage defects repair in osteoarthritis

The restoration of the degenerated articular cartilage in patients with osteoarthritis (OA) is still a challenge for researchers and clinicians. Drug interventions and surgical treatments have been widely attempted for cartilage regeneration in OA. However, the results were largely unsatisfactory. Autologous chondrocyte implantation (ACI) or matrix-induced autologous chondrocyte implantation (MACI) offers potential for the regeneration of cartilage over the long-term. However, due to the limitations and disadvantages of ACI, alternative therapies for cartilage regeneration are in need. The availability of large quantities of mesenchymal stem cells (MSCs) and the multilineage differentiation, especially their chondrogenic differentiation property, have made MSCs the most promising cell source for cartilage regeneration. In addition, MSCs have been shown the ability to undergo site-specific differentiation. MSCs can be obtained as MSC sheets using the temperature-responsive culture dish method. The MSC sheet can provide amounts of cells and extracellular matrix, which might provide the continuity between the implant and host cartilage, thus improving integrative cartilage repair. Moreover, OA is associated with progressive and often severe inflammation. MSCs not only have the ability to contribute structurally to tissue repair, but also possess potent immunomodulatory and anti-inflammatory effects. Taken together, these properties make MSC sheet promising candidate for cartilage repair in OA. We hypothesize that MSC sheet encapsulated cartilage debris can efficiently promote cartilage repair in OA patients. Chondrocytes can be obtained and cultured from small cartilage debris in vitro. Therefore, the chondrocytes may grow from the debris in cartilage defect and improve cartilage regeneration. MSC sheet provide amounts of cells, ECM and protein for cartilage regeneration and integration, and may play some roles of periosteum. The operation of MSC sheet encapsulated cartilage debris for cartilage repair is simple and practical. Moreover, the cell sheet/cartilage debris constructs can be easily shaped based on the size and shape of cartilage defects. The new method might have great potential in treating cartilage defects clinically, especially for OA patients.     

Repair of large articular cartilage defects with implants of autologous mesenchymal stem cells seeded into beta-tricalcium phosphate in a sheep model

Tissue engineering has long been investigated to repair articular cartilage defects. Successful reports have usually involved the seeding of autologous chondrocytes into polymers. Problems arise because of the scarcity of cartilage tissue biopsy material, and because the in vitro expansion of chondrocytes is difficult; to some extent, these problems limit the clinical application of this promising method. Bone marrow-derived mesenchymal stem cells (MSCs) have been proved a potential cell source because of their in vitro proliferation ability and multilineage differentiation capacity. However, in vitro differentiation will lead to high cost and always results in decreased cell viability. In this study we seeded culture-expanded autologous MSCs into bioceramic scaffold-beta-tricalcium phosphate (beta-TCP) in an attempt to repair articular cartilage defects (8 mm in diameter and 4 mm in depth) in a sheep model. Twenty-four weeks later, the defects were resurfaced with hyaline-like tissue and an ideal interface between the engineered cartilage, the adjacent normal cartilage, and the underlying bone was observed. From 12 to 24 weeks postimplantation, modification of neocartilage was obvious in the rearrangement of surface cartilage and the increase in glycosaminoglycan level. These findings suggest that it is feasible to repair articular cartilage defects with implants generated by seeding autologous MSCs, without in vitro differentiation, into beta-TCP. This approach provides great potential for clinical applications.     

Thermosensitive chitosan–Pluronic hydrogel as an injectable cell delivery carrier for cartilage regeneration

Injectable hydrogels have been studied for potential applications for articular cartilage regeneration. In this study, a thermosensitive chitosan–Pluronic (CP) hydrogel was designed as an injectable cell delivery carrier for cartilage regeneration. The CP conjugate was synthesized by grafting Pluronic onto chitosan using EDC/NHS chemistry. The sol–gel phase transition and mechanical properties of the CP hydrogel were examined by rheological experiments. The CP solution underwent a sol–gel transition around 25 °C at which the storage modulus (G′) approaches 10⁴ Pa, highlighting the potential of this material as an injectable scaffold for cartilage regeneration. The CP hydrogel was formed rapidly by increasing the temperature. The morphology of the dried CP hydrogel was observed by scanning electron microscopy. In vitro cell culture was performed using bovine chondrocytes. The proliferation of bovine chondrocytes and the amount of synthesized glycosaminoglycan increased for 28 days. These results suggested that the CP hydrogel has potential as an injectable cell delivery carrier for cartilage regeneration and could serve as a new biomaterial for tissue engineering.     

Platelet-rich plasma loaded in situ-formed hydrogel enhances hyaline cartilage regeneration by CB1 upregulation

The efficacy of three-dimensional (3D) culture on the proliferation and maturation of chondrocytes seeded into a hydrogel scaffold was assessed. Three types of hydrogel were prepared for the 3D culture of primary isolated chondrocytes. Chondrocyte proliferation was assessed using a live/dead viability/cytotoxicity assay and semiquantitative RT-PCR after 3D culture in hydrogel. Cylindrical defects in the center of rat xyphoids were used for the implantation of platelet-rich plasma (PRP)/hydrogel composites. Rats were killed at day 7 postoperatively and evaluated histochemically and immunohistologically. Xyphoid chondrocytes proliferated well with time in hydrogels. In the PRP-containing hydrogels, xyphoid defects displayed early formation of chondroid matrix with massive peripheral infiltration of spindle cells. These results were consistent with Safranin-O staining for proteoglycans and immunohistochemistry for type II collagen. Gene expression analyses in vitro revealed aggrecan, type II collagen, and ChM-1 and CB1 upregulation by PRP/hydrogel. PRP/hydrogel provided a suitable environment for hyaline cartilaginous regeneration, leading to anti-inflammation by significant increase of CB1 and inhibiting vascular ingrowth via considerable upregulation of ChM-1. The results provide a valuable reference for the clinical application of hydrogel scaffolds for hyaline cartilage regeneration, as well as the use of autologous PRP to improve cellular proliferation and maturation of xyphoid repair. ? 2012 Wiley Periodicals, Inc. J Biomed Mater Res Part A: 100A:3099-3107, 2012.     

组织工程化软骨细胞和骨髓间充质干细胞用于修复同种异体关节软骨缺损

背景：关节软骨几乎没有自身修复的能力,目前临床大多采用自体或异体软骨移植修复、软骨膜或骨膜移植修复、软骨细胞移植修复。由于自体软骨来源有限,异体软骨又存在慢性免疫排斥反应,最终可能导致预后不佳;软骨膜或骨膜移植修复的软骨易于退化,导致修复效果不佳。 目的：总结组织工程化软骨细胞、骨髓间充质干细胞及两者共培养对同种异体软骨缺损修复作用的研究现状。 方法：应用计算机检索PubMed 数据库及中国期刊网全文数据库1994-01/2012-01有关组织工程化软骨细胞和骨髓间充质干细胞用于修复同种异体关节软骨缺损方面的文章,英文检索词为“cartilage defect,allograft,chondrocyte,mesenchymal stem cells,bone marrow mesenchymal stem cells”,中文检索词为“软骨缺损,同种异体移植,软骨细胞,骨髓间充质干细胞”。排除重复性及非中英文语种研究,共保留35篇文献进行综述。 结果与结论：随着体外细胞培养方法的不断改进,现已能够把软骨细胞从坚韧的软骨中分离出来,并获得大量高纯度的软骨细胞并繁殖出新生软骨细胞。软骨细胞培养增殖能力低,传代培养容易引起老化和去分化;而成体骨髓中骨髓间充质干细胞含量少,随传代次数的增多成软骨潜能明显降低。骨髓间充质干细胞和软骨细胞共培养,两种细胞相互促进增殖和分化,作为种子细胞可减少软骨细胞增殖传代次数并节省软骨细胞数量,与组织工程支架材料复合能有效修复关节软骨缺损。     

软骨细胞微载体（Cytodex-3）平板三维培养扩增的实验研究

目的通过在微载体上进行平板培养扩增软骨细胞,并结合液态壳聚糖构建组织工程软骨。方法比较兔软骨细胞在单层培养与微载体上进行三维培养扩增软骨细胞的再分化能力。通过酶解法消化幼兔膝关节软骨后,得到种子细胞,分别进行单层和微载体三维培养扩增。通过评价细胞活性,倍增时间分析培养效果。并进行体外球型培养评价软骨细胞再分化能力,进行了糖胺多糖的定量生化分析。三维培养扩增软骨细胞与壳聚糖复合构建组织工程软骨,培养21天后通过组织学特种染色鉴定构建组织特性。结果微载体培养的软骨细胞可以保持良好活力和再分化能力,与单层培养体系相比较,糖胺多糖的定量生化分析（30．417±1．116ugGAG／mg样本）和（45．122±1．239ugGAG／mg样本）的差异具有统计学意义（P〈0．05）。结论在微载体上进行三维培养扩增软骨细胞可以加强细胞再分化能力。软骨细胞与壳聚糖合成后,可以在体外形成形态稳定的组织工程软骨。     

The use of absorbable co-polymer pads with alginate and cells for articular cartilage repair in rabbits

PURPOSE: To determine the effect of polyglycolic acid (PGA)-polylactic acid (PLA) co-polymer pads with calcium alginate on chondrogenic gene expression for chondrocytes cultured in vitro. We also evaluated the ability of these absorbable pads with alginate to deliver chondrocytes and influence osteochondral defect repair in vivo in immature rabbit knees. METHODS: Rabbit rib chondrocytes were suspended in calcium alginate and co-polymer pads composed of either 47.5/52.5 PGA-PLA or 90/10 PGA-PLA at two different cell concentrations and cultured in vitro for 1, 3, and 5 days. Analysis was performed using RT-PCR for chondrogenic gene expression of aggrecan, type II collagen, and type I collagen. Cells labeled with a traceable green fluorescent protein (GFP) marker in vitro were suspended within the pads to analyze for dispersion and attachment to the pad. An in vivo study was performed in which full-thickness (3x4mm(2)) osteochondral defects were made in 60 rabbit knees. The study comprised four treatment groups based on the type of implant into the defect (empty, alginate alone, or either type of co-polymer pad) and harvested at either 6 or 12 weeks. Two independent blinded observers analyzed and scored the defects grossly and histologically. RESULTS: In vitro analysis of the chondrocytes after 1, 3, and 5 days in culture showed no statistical differences between the types of PGA/PLA co-polymer pad with regard to expression of aggrecan, type II collagen, or type I collagen. However, although statistically insignificant, the expression of aggrecan and type II collagen was found to be greater than that for type I collagen in both types of pads, confirming the chondrogenic effect of suspension culture for this system. The addition of alginate to polymer pads allowed costal chondrocytes to be implanted in vivo, as evidenced by the attachment of the cells to the fibers and the uniform dispersion of the GFP-labeled cells through the pad as seen on fluorescent microscopy. Histologic results showed improved scores for the 47.5/52.5 PGA-PLA group (21.3) and the 90/10 PGA-PLA group (18.3) when compared to empty (15.3) or alginate alone (15.1) defects at 12 weeks. CONCLUSION: The addition of calcium alginate to the co-polymer pads offers a new approach to deliver cells to an osteochondral defect and may enhance cartilage regeneration. Future application of this model may allow for an arthroscopic delivery system to assist the healing of cartilage defects.     

The regulation of expanded human nasal chondrocyte re-differentiation capacity by substrate composition and gas plasma surface modification

Optimizing re-differentiation of clinically relevant cell sources on biomaterial substrates in serum containing (S+) and serum-free (SF) media is a key consideration in scaffold-based articular cartilage repair strategies. We investigated whether the adhesion and post-expansion re-differentiation of human chondrocytes could be regulated by controlled changes in substrate surface chemistry and composition in S+ and SF media following gas plasma (GP) treatment. Expanded human nasal chondrocytes were plated on gas plasma treated (GP+) or untreated (GP-) poly(ethylene glycol)-terephthalate-poly(butylene terephthalate) (PEGT/PBT) block co-polymer films with two compositions (low or high PEG content). Total cellularity, cell morphology and immunofluorescent staining of vitronectin (VN) and fibronectin (FN) integrin receptors were evaluated, while post-expansion chondrogenic phenotype was assessed by collagen types I and II mRNA expression. We observed a direct relationship between cellularity, cell morphology and re-differentiation potential. Substrates supporting high cell adhesion and a spread morphology (i.e. GP+ and low PEG content films), resulted in a significantly greater number of cells expressing alpha5beta1 FN to alpha(V)beta3 VN integrin receptors, concomitant with reduced collagen type II/ImRNA gene expression. Substrates supporting low cell adhesion and a spherical morphology (GP- and high PEG content films) promoted chondrocyte re-differentiation indicated by high collagen type II/I gene expression and a low percentage of alpha5beta1 FN integrin expressing cells. This study demonstrates that cell-substrate interactions via alpha5beta1 FN integrin mediated receptors negatively impacts expanded human nasal chondrocyte re-differentiation capacity. GP treatment promotes cell adhesion in S+ media but reverses the ability of low PEG content PEGT/PBT substrates to maintain chondrocyte phenotype. We suggest alternative cell immobilization techniques to GP are necessary for clinical application in articular cartilage repair.     

The repair of osteochondral defects using baculovirus-mediated gene transfer with de-differentiated chondrocytes in bioreactor culture

Baculovirus has emerged as a promising gene delivery vector. Hereby de-differentiated rabbit chondrocytes were transduced ex vivo with a recombinant baculovirus expressing BMP-2 (Bac-CB), seeded to scaffolds and cultured statically for 1 day (Bac-w0 group) or in a rotating-shaft bioreactor (RSB) for 1 week (Bac-w1 group) or 3 weeks (Bac-w3 group). Mock-transduced constructs were cultured statically for 1 day to serve as the control (Mock-w0 group). We unraveled that Bac-CB transduction and increasing culture time in the RSB yielded more mature cartilaginous constructs in vitro. Eight weeks after implanting into the rabbit osteochondral defects, Mock-w0 constructs failed to repair the lesion while Bac-w0 constructs resulted in augmented, yet incomplete, repair. Bac-w1 constructs yielded neocartilage layers rich in glycosaminoglycans and collagen II, but the integration between the graft and host cartilages was not complete. In contrast, Bac-w3 constructs led to the regeneration of hyaline cartilages as characterized by cartilage-like appearance, improved integration, chondrocytes clustered in lacunae, smooth and homogeneous matrix rich in collagen II and glycosaminoglycans but deficient in collagen I. In conclusion, combining baculovirus-modified de-differentiated chondrocytes and RSB culture creates constructs that repair osteochondral defects, and in vitro culture time dictates the construct maturation and subsequent in vivo repair.     

β-Defensin-4 (HBD-4) is expressed in chondrocytes derived from normal and osteoarthritic cartilage encapsulated in PEGDA scaffold

Defensins are antibiotic peptides involved in host defense mechanisms, wound healing and tissue repair. Furthermore, they seem to play an important role in protection mechanisms in articular joints. The aim of this study was to investigate β-defensin-4 expression in chondrocytes taken from articular cartilage of knees of patients with osteoarthritis (OA) compared to normal cartilage, in vivo in explanted tissue, and in vitro in chondrocytes encapsulated in construct PEGDA hydrogels. The present investigation was conducted to try and elucidate the possible use of β-defensin-4 as a relevant marker for the eventual use of successive scaffold allografts, and to provide new insights for hydrogel PEGDA scaffold efficacy in re-differentiation or repair of OA chondrocytes in vitro. Articular cartilage specimens from OA cartilage and normal cartilage were assessed by histology, histochemistry, immunohistochemistry and Western blot analysis. The results showed strong β-defensin-4 immunoexpression in explanted tissue from OA cartilage and weak β-defensin-4 expression in control cartilage. The chondrocytes from OA cartilage after 4 weeks of culture in PEGDA hydrogels showed the formation of new hyaline cartilage and a decreased expression of β-defensin-4 immunostaining comparable to that of control cartilage. Our results suggest the possibility of applying autologous cell transplantation in conjunction with scaffold materials for repair of cartilage lesions in patients with OA using β-defensin-4 as a relevant marker.