Bio‐inspired design of a magnetically active trilayered scaffold for cartilage tissue engineering

An important topic in cartilage tissue engineering is the development of biomimetic scaffolds which mimic the depth‐dependent material properties of the native tissue. We describe an advanced trilayered nanocomposite hydrogel (ferrogel) with a gradient in compressive modulus from the top to the bottom layers (p < 0.05) of the construct. Further, the scaffold was able to respond to remote external stimulation, exhibiting an elastic, depth‐dependent strain gradient. When bovine chondrocytes were seeded into the ferrogels and cultured for up to 14 days, there was good cell viability and a biochemical gradient was measured with sulphated glycosaminoglycan increasing with depth from the surface. This novel construct provides tremendous scope for tailoring location‐specific cartilage replacement tissue; by varying the density of magnetic nanoparticles, concentration of base hydrogel and number of cells, physiologically relevant depth‐dependent gradients may be attained. © 2015 The Authors Journal of Tissue Engineering and Regenerative Medicine Published by John Wiley & Sons Ltd.     

组织工程化软骨修复界面整合的体外模型

背景：随着组织工程学的发展,自体软骨细胞移植技术经常被用来修复软骨缺损,整合不良是导致修复失败的原因之一。许多体外模型被用来进行这方面的研究。 目的：建立一种组织工程化软骨修复界面整合的体外实验模型并评价其效果。 方法：制备猪体外软骨整合模型,获得21个软骨环,18只琼脂糖凝胶覆盖的软骨环设为琼脂糖凝胶组,剩余3个做无琼脂糖对照组,分别植入分离的软骨细胞,观察近期软骨环边界细胞漏出情况,分别在1,2,4周做切片、染色并行组织学观察,测量新生软骨平均面积并进行比较。 结果与结论：无琼脂糖对照组由于软骨细胞早期从软骨环底部漏出,未能在软骨环中形成软骨细胞聚集,所以未做后期处理,而琼脂糖凝胶组则未发生。琼脂糖凝胶组1,2,4周做切片并行固定后组织切片分别用苏木精-伊红染色、阿利新蓝、番红O、Ⅱ型胶原免疫组化染色,移植的软骨细胞在软骨环内不断增殖,并且产生细胞外基质。在第1,2周的孵育中,新生软骨的面积明显增大,到第4周时,面积也有进一步增加,但是第2-4周的面积增加,差异无显著性意义（P〉0.05）。模型成功模拟了自体软骨细胞移植修复关节软骨缺损的体外整合过程,未来可应用于软骨整合及软骨组织工程的机制研究。     

Co-culture in cartilage tissue engineering

For biotechnological research in vitro in general and tissue engineering specifically, it is essential to mimic the natural conditions of the cellular environment as much as possible. In choosing a model system for in vitro experiments, the investigator always has to balance between being able to observe, measure or manipulate cell behaviour and copying the in situ environment of that cell. Most tissues in the body consist of more than one cell type. The organization of the cells in the tissue is essential for the tissue's normal development, homeostasis and repair reaction. In a co-culture system, two or more cell types brought together in the same culture environment very likely interact and communicate. Co-culture has proved to be a powerful in vitro tool in unravelling the importance of cellular interactions during normal physiology, homeostasis, repair and regeneration. The first co-culture studies focused mainly on the influence of cellular interactions on oocytes maturation to a pre-implantation blastocyst. Therefore, a brief overview of these studies is given here. Later on in the history of co-culture studies, it was applied to study cell-cell communication, after which, almost immediately as the field of tissue engineering was recognized, it was introduced in tissue engineering to study cellular interactions and their influence on tissue formation. This review discusses the introduction and applications of co-culture systems in cell biology research, with the emphasis on tissue engineering and its possible application for studying cartilage regeneration.     

Characterization of costal cartilage and its suitability as a cell source for articular cartilage tissue engineering

Costal cartilage is a promising donor source of chondrocytes to alleviate cell scarcity in articular cartilage tissue engineering. Limited knowledge exists, however, on costal cartilage characteristics. This study describes the characterization of costal cartilage and articular cartilage properties and compares neocartilage engineered with costal chondrocytes to native articular cartilage, all within a sheep model. Specifically, we (a) quantitatively characterized the properties of costal cartilage in comparison to patellofemoral articular cartilage, and (b) evaluated the quality of neocartilage derived from costal chondrocytes for potential use in articular cartilage regeneration. Ovine costal and articular cartilages from various topographical locations were characterized mechanically, biochemically, and histologically. Costal cartilage was stiffer in compression but softer and weaker in tension than articular cartilage. These differences were attributed to high amounts of glycosaminoglycans and mineralization and a low amount of collagen in costal cartilage. Compared to articular cartilage, costal cartilage was more densely populated with chondrocytes, rendering it an excellent chondrocyte source. In terms of tissue engineering, using the self‐assembling process, costal chondrocytes formed articular cartilage‐like neocartilage. Quantitatively compared via a functionality index, neocartilage achieved 55% of the medial condyle cartilage mechanical and biochemical properties. This characterization study highlighted the differences between costal and articular cartilages in native forms and demonstrated that costal cartilage is a valuable source of chondrocytes suitable for articular cartilage regeneration strategies.     

Efficacy of thermoresponsive,photocrosslinkable hydrogels derived from decellularized tendon and cartilage extracellular matrix for cartilage tissue engineering

Tissue engineering using adult mesenchymal stem cells (MSCs), a promising approach for cartilage repair, is highly dependent on the nature of the matrix scaffold. Thermoresponsive, photocrosslinkable hydrogels were fabricated by functionalizing pepsin‐soluble decellularized tendon and cartilage extracellular matrices (ECM) with methacrylate groups. Methacrylated gelatin hydrogels served as controls. When seeded with human bone marrow MSCs and cultured in chondrogenic medium, methacrylated ECM hydrogels experienced less cell‐mediated contraction, as compared against non‐methacrylated ECM hydrogels. However, methacrylation slowed or diminished chondrogenic differentiation of seeded MSCs, as determined through analyses of gene expression, biochemical composition and histology. In particular, methacrylated cartilage hydrogels supported minimal due to chondrogenesis over 42 weeks, as hydrogel disintegration beginning at day 14 presumably compromised cell–matrix interactions. As compared against methacrylated gelatin hydrogels, MSCs cultured in non‐methacrylated ECM hydrogels exhibited comparable expression of chondrogenic genes (Sox9, Aggrecan and collagen type II) but increased collagen type I expression. Non‐methacrylated cartilage hydrogels did not promote chondrogenesis to a greater extent than either non‐methacrylated or methacrylated tendon hydrogels. Whereas methacrylated gelatin hydrogels supported relatively homogeneous increases in proteoglycan and collagen type II deposition throughout the construct over 42 days, ECM hydrogels possessed greater heterogeneity of staining intensity and construct morphology. These results do not support the utility of pepsin‐solubilized cartilage and tendon hydrogels for cartilage tissue engineering over methacrylated gelatin hydrogels. Methacrylation of tendon and cartilage ECM hydrogels permits thermal‐ and light‐induced polymerization but compromises chondrogenic differentiation of seeded MSCs.     

Polysaccharide‐based materials for cartilage tissue engineering applications

Tissue engineering was proposed approximately 15 years ago as an alternative and innovative way to address tissue regeneration problems. During the development of this field, researchers have proposed a variety of ways of looking into the regeneration and engineering of tissues, using different types of materials coupled with a wide range of cells and bioactive agents. This trilogy is commonly considered the basis of a tissue‐engineering strategy, meaning by this the use of a support material, cells and bioactive agents. Different researchers have been adding to these basic approaches other parameters able to improve the functionality of the tissue‐engineered construct, such as specific mechanical environments and conditioned gaseous atmospheres, among others. Nowadays, tissue‐engineering principles have been applied, with different degrees of success, to almost every tissue lacking efficient regeneration ability and the knowledge and intellectual property produced since then has experienced an immense growth. Materials for regenerating tissues, namely cartilage, have also been continuously increasing and most of the theoretical requirements for a tissue engineering support have been addressed by a single material or a mixture of materials. Due to their intrinsic features, polysaccharides are interesting for cartilage tissue‐engineering approaches and as a result their exploitation for this purpose has been increasing. The present paper intends to provide an overview of some of the most relevant polysaccharides used in cartilage tissue‐engineering research. Copyright © 2010 John Wiley & Sons, Ltd.     

Platelet‐rich plasma enhances the integration of bioengineered cartilage with native tissue in an in vitro model

Current therapies for cartilage repair can be limited by an inability of the repair tissue to integrate with host tissue. Thus, there is interest in developing approaches to enhance integration. We have previously shown that platelet‐rich plasma (PRP) improves cartilage tissue formation. This raised the question as to whether PRP could promote cartilage integration . Chondrocytes were isolated from cartilage harvested from bovine joints, seeded on a porous bone substitute and grown in vitro to form an osteochondral‐like implant. After 7 days, the biphasic construct was soaked in PRP for 30 min before implantation into the core of a donut‐shaped biphasic explant of native cartilage and bone. Controls were not soaked in PRP. The implant–explant construct was cultured for 2–4 weeks. PRP‐soaked bioengineered implants integrated with host tissue in 73% of samples, whereas controls only integrated in 19% of samples. The integration strength, as determined by a push‐out test, was significantly increased in the PRP‐soaked implant group (219 ± 35.4 kPa) compared with controls (72.0 ± 28.5 kPa). This correlated with an increase in glycosaminoglycan and collagen accumulation in the region of integration in the PRP‐treated implant group, compared with untreated controls. Immunohistochemical studies revealed that the integration zone contained collagen type II and aggrecan. The cells at the zone of integration in the PRP‐soaked group had a 3.5‐fold increase in matrix metalloproteinase‐13 gene expression compared with controls. These results suggest that PRP‐soaked bioengineered cartilage implants may be a better approach for cartilage repair due to enhanced integration.     

Fate of modular cardiac tissue constructs in a syngeneic rat model

Modular cardiac tissues developed both vascular and cardiac structures in vivo, provided that the host response was attenuated by omitting xenoproteins from the modules. Collagen gel modules (with Matrigel^TM) containing cardiomyocytes (CMs) alone or CMs with surface‐seeded endothelial cells (ECs; CM/EC modules) were injected into the peri‐infarct zone of the heart in syngeneic Lewis rats. After 3 weeks, donor ECs developed into blood vessel‐like structures that also contained erythrocytes. However, no donor CMs were found within the implant sites, presumably because host cells including macrophages and T cells infiltrated extensively into the injection sites. To lessen the host response, Matrigel was omitted from the matrix and the modules were rinsed with serum‐free medium prior to implantation. Host cell infiltration was attenuated, resulting in a higher degree of vascularization with CM/EC modules than with CM modules without ECs. Most importantly, donor CMs matured into striated muscle‐like structures in Matrigel‐free implants. Copyright © 2013 John Wiley & Sons, Ltd.     

Processed xenogenic cartilage as innovative biomatrix for cartilage tissue engineering: effects on chondrocyte differentiation and function

One key point in the development of new bioimplant matrices for the reconstruction and replacement of cartilage defects is to provide an adequate microenvironment to ensure chondrocyte migration and de novo synthesis of cartilage‐specific extracellular matrix (ECM). A recently developed decellularization and sterilization process maintains the three‐dimensional (3D) collagen structure of native septal cartilage while increasing matrix porosity, which is considered to be crucial for cartilage tissue engineering. Human primary nasal septal chondrocytes were amplified in monolayer culture and 3D‐cultured on processed porcine nasal septal cartilage scaffolds. The influence of chondrogenic growth factors on neosynthesis of ECM proteins was examined at the protein and gene expression levels. Seeding experiments demonstrated that processed xenogenic cartilage matrices provide excellent environmental properties for human nasal septal chondrocytes with respect to cell adhesion, migration into the matrix and neosynthesis of cartilage‐specific ECM proteins, such as collagen type II and aggrecan. Matrix biomechanical stability indicated that the constructs retrieve full stability and function during 3D culture for up to 42 days, proportional to collagen type II and GAG production. Thus, processed xenogenic cartilage offers a suitable environment for human nasal chondrocytes and has promising potential for cartilage tissue engineering in the head and neck region. Copyright © 2012 John Wiley & Sons, Ltd.     

Establishment of an in vitro three‐dimensional model for cartilage damage in rheumatoid arthritis

Rheumatoid arthritis (RA) is a chronic inflammatory disease that leads to progressive joint destruction. To further understand the process of rheumatoid cartilage damage, an in vitro model consisting of an interactive tri‐culture of synovial fibroblasts (SFs), LPS‐stimulated macrophages and a primary chondrocyte‐based tissue‐engineered construct was established. The tissue‐engineered construct has a composition similar to that of human cartilage, which is rich in collagen type II and proteoglycans. Data generated from this model revealed that healthy chondrocytes were activated in the presence of SFs and macrophages. The activated chondrocytes subsequently displayed aberrant behaviours as seen in a disease state such as increased apoptosis, decreased gene expression for matrix components such as type II collagen and aggrecan, increased gene expression for tissue‐degrading enzymes (MMP‐1, ‐3, ‐13 and ADAMTS‐4, ‐5), and upregulation of inflammatory mediator gene expression (TNF‐α, IL‐1β, IL‐6 and IKBKB). Additionally, the inclusion of SFs and macrophages in the model enabled both cell types to more closely replicate an in vivo role in mediating cartilage destruction. This is evidenced by extensive matrix loss, detected in the model through immunostaining and biochemical analysis. Subsequent drug treatment with celecoxib has shown that the model was able to respond to the therapeutic effects of this drug by reversing cartilage damage. This study showed that the model was able to recapitulate certain pathological features of an RA cartilage. If properly validated, this model potentially can be used for screening new therapeutic drugs and strategies, thereby contributing to the improvement of anti‐rheumatic treatment. Copyright © 2017 John Wiley & Sons, Ltd.     

Chondrogenic potential of electrospun nanofibres for cartilage tissue engineering

Articular cartilage has a heterogeneous structure, comprising elongated cells at the articulating surface and rounded cells elsewhere. This feature poses a complex challenge when fabricating 3D tissue engineering scaffolds able to mimic the native extracellular matrix (ECM) of cartilage for tissue repair and regeneration. Nanofibre scaffolds can provide an ECM-like structure, but are mechanically weak and typically have subcellular pore geometries. In this study, the use of poly(L,D-lactide) (PLDLA) nanofibre coatings on PLDLA microfibres or films (nanofibre composites) to influence bovine chondrocyte behaviour was investigated. It was demonstrated that electrospun nanofibres facilitated the adhesion of chondrocytes and helped to maintain smaller projected cell areas and a rounded cell phenotype, when compared to PLDLA films or microfibres. Random nanofibre composites were associated with the smallest and most rounded cells and aligned nanofibre composites also demonstrated a similar tendency. Quantitative PCR revealed that nanofibres promoted the expression of chondrogenic markers, such as collagen type IIaI and aggrecan, while maintaining low levels of collagen IaI. It was also found, by water contact angle measurement, that nanofibres were significantly more hydrophobic than cast films. The lower wettability of polymeric nanofibres favoured the maintenance of rounded chondrocyte morphology. To our knowledge this is the first study to confirm the positive influence on preserving chondrogenic phenotype and gene expression at the interface of true nano-microfibrous composites by using individual microfibres coated with aligned nanofibres. Such composites can potentially be fabricated into mechanically durable 3D scaffolds with better cell infiltration throughout the scaffolds.     

Design of semi-degradable hydrogels based on poly(vinyl alcohol) and poly(lactic-co-glycolic acid) for cartilage tissue engineering

Articular cartilage damage is a persistent challenge in biomaterials and tissue engineering. Poly(vinyl alcohol) (PVA) hydrogels have shown promise as implants, but their lack of integration with surrounding cartilage prevents their utility. We sought to combine the advantages of PVA hydrogels with poly(lactic-co-glycolic acid) (PLGA) scaffolds, which have been successful in facilitating the integration of neocartilage with surrounding tissue. Through a novel double-emulsion technique, PLGA microparticles and a high level of porosity were simultaneously incorporated into PVA hydrogels. The porosity, average pore size and swelling properties of the hydrogels were controlled by varying initial processing parameters, such as the relative amounts of PLGA and solvent. Average pore sizes were in the ranged 50-100 μm. The PLGA microparticles degraded within the hydrogels over time in aqueous conditions, resulting in increases in porosity and pore size. After 4 weeks in cell culture, immature cartilage tissue filled many of the pores of the hydrogels that initially contained PLGA, and proteoglycan production was proportional to the amount of PLGA. In contrast, there was little cell attachment and no proteoglycan production in control hydrogels without PLGA. The compressive moduli of the hydrogels were similar to that of healthy cartilage and increased over time from 0.05-0.1 to 0.3-0.7 MPa. The generation of a hybrid cartilage-hydrogel construct using this technique may finally allow the integration of PVA hydrogels with surrounding cartilage.     

Scaffold‐free cartilage subjected to frictional shear stress demonstrates damage by cracking and surface peeling

Scaffold‐free engineered cartilage is being explored as a treatment for osteoarthritis. In this study, frictional shear stress was applied to determine the friction and damage behaviour of scaffold‐free engineered cartilage, and tissue composition was investigated as it related to damage. Scaffold‐free engineered cartilage frictional shear stress was found to exhibit a time‐varying response similar to that of native cartilage. However, damage occurred that was not seen in native cartilage, manifesting primarily as tearing through the central plane of the constructs. In engineered cartilage, cells occupied a significantly larger portion of the tissue in the central region where damage was most prominent (18 ± 3% of tissue was comprised of cells in the central region vs 5 ± 1% in the peripheral region; p < 0.0001). In native cartilage, cells comprised 1–4% of tissue for all regions. Average bulk cellularity of engineered cartilage was also greater (68 × 10³ ± 4 × 10³ vs 52 × 10³ ± 22 × 10³ cells/mg), although this difference was not significant. Bulk tissue comparisons showed significant differences between engineered and native cartilage in hydroxyproline content (8 ± 2 vs 45 ± 3 µg HYP/mg dry weight), solid content (12.5 ± 0.4% vs 17.9 ± 1.2%), shear modulus (0.06 ± 0.02 vs 0.15 ± 0.07 MPa) and aggregate modulus (0.12 ± 0.03 vs 0.32 ± 0.14 MPa), respectively. These data indicate that enhanced collagen content and more uniform extracellular matrix distribution are necessary to reduce damage susceptibility. Copyright © 2014 John Wiley & Sons, Ltd.     

Effect of cell seeding concentration on the quality of tissue engineered constructs loaded with adult human articular chondrocytes

Many aspects of the process of in vitro differentiation of chondrocytes in three-dimensional (3D) scaffolds need to be further investigated. Chitosan scaffolds were produced by freeze-drying 3% w/v 90% DDA chitosan gels. The effect of the cell seeding concentration was evaluated by culturing human adult chondrocytes in chitosan scaffolds After the first passage, cells were seeded into chitosan scaffolds with a diameter of 8 mm. The final cell seeding concentration per cm3 of chitosan scaffold was: Group A, 3 x 10(6); Group B, 6 x 10(6); Group C, 12 x 10(6); and Group D, 25 x 10(6) cells. After 14 and 28 days in 3D culture, the constructs were assesed for collagen, glucosaminoglycans and DNA content. The mechanical properties of the constructs were determined using a dynamic oscillatory shear test. The histological aspect of the constructs was evaluated using the Bern score. The collagen and GAG concentration increased, varying the cell seeding concentration. There was a significant increase in proteoglycan and hydroxyproline production between groups C and D. The sulphated GAG content increased significantly in the group D as compared to the other groups. The mechanical properties of the different constructs increased over time, from 9.6 G'/kPa at 14 days of 3D culture to 14.6 G'/kPa at 28 days under the same culture conditions. In this study we were able to determine that concentrations of 12-25 million cells/cm2 are needed to increase the matrix production and mechanical properties of human adult chondrocytes under static conditions.     

间充质干细胞在关节软骨组织工程中的应用

背景：组织工程技术的发展为关节软骨缺损修复和功能重建提供了新的方法和思路。目的：探讨以间充质干细胞作为种子细胞在关节软骨组织工程中的应用和研究进展。 方法：由第一作者检索 PubMed 数据库中2000-01-01/2014-09-30有关间充质干细胞和关节软骨组织工程的文献,检索词为“articular cartilage defects, cartilage tissue engineering, mesenchymal stem cel s”。共检索到70篇相关文献,对其中49篇文献进行综述。 结果与结论：关节软骨缺损自身修复能力很有限,目前的临床治疗手段无法达到满意修复,而组织工程的发展为解决这个问题提供了新思路。在种子细胞选择方面,软骨细胞去分化能力有限,胚胎干细胞受到伦理、法律等方面的制约,而间充质干细胞因其自体来源、易扩增、具有软骨分化潜能而受到广泛重视。但目前应用组织工程方法修复关节软骨缺损的效果存在一定的争议,主要是远期功能距离临床应用存在一定差距,在修复组织结构和生物力学方面还需要进一步研究。     

Three‐dimensional assembly of tissue‐engineered cartilage constructs results in cartilaginous tissue formation without retainment of zonal characteristics

Articular cartilage has limited regenerative capabilities. Chondrocytes from different layers of cartilage have specific properties, and regenerative approaches using zonal chondrocytes may yield better replication of the architecture of native cartilage than when using a single cell population. To obtain high seeding efficiency while still mimicking zonal architecture, cell pellets of expanded deep zone and superficial zone equine chondrocytes were seeded and cultured in two layers on poly(ethylene glycol)‐terephthalate–poly(butylene terephthalate) (PEGT–PBT) scaffolds. Scaffolds seeded with cell pellets consisting of a 1:1 mixture of both cell sources served as controls. Parallel to this, pellets of superficial or deep zone chondrocytes, and combinations of the two cell populations, were cultured without the scaffold. Pellet cultures of zonal chondrocytes in scaffolds resulted in a high seeding efficiency and abundant cartilaginous tissue formation, containing collagen type II and glycosaminoglycans (GAGs) in all groups, irrespective of the donor (n = 3), zonal population or stratified scaffold‐seeding approach used. However, whereas total GAG production was similar, the constructs retained significantly more GAG compared to pellet cultures, in which a high percentage of the produced GAGs were secreted into the culture medium. Immunohistochemistry for zonal markers did not show any differences between the conditions. We conclude that spatially defined pellet culture in 3D scaffolds is associated with high seeding efficiency and supports cartilaginous tissue formation, but did not result in the maintenance or restoration of the original zonal phenotype. The use of pellet‐assembled constructs leads to a better retainment of newly produced GAGs than the use of pellet cultures alone. Copyright © 2013 John Wiley & Sons, Ltd.     

Effect of visco‐elastic silk–chitosan microcomposite scaffolds on matrix deposition and biomechanical functionality for cartilage tissue engineering

Commonly used polymer‐based scaffolds often lack visco‐elastic properties to serve as a replacement for cartilage tissue. This study explores the effect of reinforcement of silk matrix with chitosan microparticles to create a visco‐elastic matrix that could support the redifferentiation of expanded chondrocytes. Goat chondrocytes produced collagen type II and glycosaminoglycan (GAG)‐enriched matrix on all the scaffolds (silk:chitosan 1:1, 1:2 and 2:1). The control group of silk‐only constructs suffered from leaching out of GAG molecules into the medium. Chitosan‐reinforced scaffolds retained a statistically significant (p < 0.02) higher amount of GAG, which in turn significantly increased (p < 0.005) the aggregate modulus (as compared to silk‐only controls) of the construct akin to that of native tissue. Furthermore, the microcomposite constructs demonstrated highly pronounced hysteresis at 4% strain up to 400 cycles, mimicking the visco‐elastic properties of native cartilage tissue. These results demonstrated a step towards optimizing the design of biomaterial scaffolds used for cartilage tissue engineering. Copyright © 2015 John Wiley & Sons, Ltd.     

同种异体组织工程预定形态软骨的研究

目的研究以聚羟基乙酸(Polyglycolicacid,PGA)为细胞支架同种异体预定形态组织工程化软骨在有免疫力的动物体内构建的可行性。方法取1周龄乳兔肋软骨和关节软骨,收集体外培养第3～4代的软骨细胞,接种于塑为管状和片状经多聚赖氨酸处理的PGA材料上。分别于6、12周取材,行大体和组织学观察评价。结果软骨细胞-PGA复合物体外培养1周有基质产生。种植6周后,管状和片状复合物生成软骨,结缔组织内可见炎细胞;12周时软骨细胞成熟。结论同种异体软骨细胞与PGA所形成的复合物在有免疫力的动物体内可构建出预定形态软骨。     

Evaluation of articular cartilage repair using biodegradable nanofibrous scaffolds in a swine model: a pilot study

The aim of this study was to evaluate a cell‐seeded nanofibrous scaffold for cartilage repair in vivo. We used a biodegradable poly(ε‐caprolactone) (PCL) nanofibrous scaffold seeded with allogeneic chondrocytes or xenogeneic human mesenchymal stem cells (MSCs), or acellular PCL scaffolds, with no implant as a control to repair iatrogenic, 7 mm full‐thickness cartilage defects in a swine model. Six months after implantation, MSC‐seeded constructs showed the most complete repair in the defects compared to other groups. Macroscopically, the MSC‐seeded constructs regenerated hyaline cartilage‐like tissue and restored a smooth cartilage surface, while the chondrocyte‐seeded constructs produced mostly fibrocartilage‐like tissue with a discontinuous superficial cartilage contour. Incomplete repair containing fibrocartilage or fibrous tissue was found in the acellular constructs and the no‐implant control group. Quantitative histological evaluation showed overall higher scores for the chondrocyte‐ and MSC‐seeded constructs than the acellular construct and the no‐implant groups. Mechanical testing showed the highest equilibrium compressive stress of 1.5 MPa in the regenerated cartilage produced by the MSC‐seeded constructs, compared to 1.2 MPa in the chondrocyte‐seeded constructs, 1.0 MPa in the acellular constructs and 0.2 MPa in the no‐implant group. No evidence of immune reaction to the allogeneically‐ and xenogeneically‐derived regenerated cartilage was observed, possibly related to the immunosuppressive activities of MSCs, suggesting the feasibility of allogeneic or xenogeneic transplantation of MSCs for cell‐based therapy. Taken together, our results showed that biodegradable nanofibrous scaffolds seeded with MSCs effectively repair cartilage defects in vivo, and that the current approach is promising for cartilage repair. Copyright © 2008 John Wiley & Sons, Ltd.     

An additive manufacturing‐based PCL–alginate–chondrocyte bioprinted scaffold for cartilage tissue engineering

Regenerative medicine is targeted to improve, restore or replace damaged tissues or organs using a combination of cells, materials and growth factors. Both tissue engineering and developmental biology currently deal with the process of tissue self‐assembly and extracellular matrix (ECM) deposition. In this investigation, additive manufacturing (AM) with a multihead deposition system (MHDS) was used to fabricate three‐dimensional (3D) cell‐printed scaffolds using layer‐by‐layer (LBL) deposition of polycaprolactone (PCL) and chondrocyte cell‐encapsulated alginate hydrogel. Appropriate cell dispensing conditions and optimum alginate concentrations for maintaining cell viability were determined. In vitro cell‐based biochemical assays were performed to determine glycosaminoglycans (GAGs), DNA and total collagen contents from different PCL–alginate gel constructs. PCL–alginate gels containing transforming growth factor‐β (TGFβ) showed higher ECM formation. The 3D cell‐printed scaffolds of PCL–alginate gel were implanted in the dorsal subcutaneous spaces of female nude mice. Histochemical [Alcian blue and haematoxylin and eosin (H&E) staining] and immunohistochemical (type II collagen) analyses of the retrieved implants after 4 weeks revealed enhanced cartilage tissue and type II collagen fibril formation in the PCL–alginate gel (+TGFβ) hybrid scaffold. In conclusion, we present an innovative cell‐printed scaffold for cartilage regeneration fabricated by an advanced bioprinting technology. Copyright © 2013 John Wiley & Sons, Ltd.