Application of high throughput perfusion micro 3-D cell culture platform for the precise study of cellular responses to extracellular conditions -effect of serum concentrations on the physiology of articular chondrocytes

Mammalian cells are sensitive to extracellular microenvironments. In order to faithfully explore the physiological responses of cells to extracellular conditions, a steady, homogenous, and three-dimensional (3-D) culture environment is required because it can provide a more quantifiable and biologically-relevant culture condition. To achieve this, this study reports a perfusion micro cell culture platform encompassing 22 microbioreactor units for high throughput 3-D cell culture. The cell culture platform structurally consisting of a plug and a microbioreactor chamber module was simply fabricated by replica molding of polydimethylsiloxane (PDMS) polymer. The platform features in the proposed plug module with multiple molds incorporated, facilitating the preparation of cell encapsulated 3-D hydrogel constructs in a precise and efficient manner. This trait is found particularly useful for high-precision and high-throughput micro 3-D cell culture-based assay. In this study, the real value of the proposed platform to maintain a stable and homogenous culture condition was discussed. Besides, the application of the presented platform for precisely investigating the effect of serum concentration on the metabolic activities and biosynthetic abilities of articular chondrocytes was also demonstrated. As a whole, the proposed device has paved an alternative route to carry out high throughput micro-scale 3-D perfusion cell culture in a simple, cost-effective and precise manner. The promising applications include 3-D cell culture-based high throughput drug or toxicity testing/screening, or other investigations on the cell biology, where the precise quantification of the links between the cellular responses and extracellular conditions is required.     

A study of the structural response of wet hyaline cartilage to various loading situations

A direct view has been obtained of the manner in which the fibrous components components and chondrocytes in hyaline cartilage respond to the application of uniaxial tensile loading and plane-strain compressive loading. A micro-mechanical testing device has been developed which inserts directly into the stage of a high-resolution optical microscope fitted with Nomarski interference contrast and this has permitted simultaneous morphological and mechanical observations to be conducted on articular cartilage maintained in its wet functional condition. Aligned and crimped fibrous arrays surround the deeper chondrocytes and can be observed to undergo well-defined geometric changes with applied stress. It is thought that these arrays may act as displacement or strain sensors transmitting mechanical information from the bulk matrix to their associated cells thus inducing a specific metabolic response. The process of tissue recovery following sustained high levels of compressive loading can also be observed with this experimental technique.     

Biomechanical analysis of a chondrocyte-based repair model of articular cartilage.

The objective of this study was to evaluate the biomechanical properties of newly formed cartilaginous tissue synthesized from isolated chondrocytes. Cartilage from articular joints of lambs was either digested in collagenase to isolated chondrocytes or cut into discs that were devitalized by multiple freeze-thaw cycles. Isolated cells were incubated in suspension culture in the presence of devitalized cartilage matrix for 3 weeks. Multiple chondrocyte/matrix constructs were assembled with fibrin glue and implanted subcutaneously in nude mice for up to 6 weeks. Testing methods were devised to quantify integration of cartilage pieces and mechanical properties of constructs. These studies showed monotonic increase with time in tensile strength, fracture strain, fracture energy, and tensile modulus to values 5-10% of normal articular cartilage by 6 weeks in vivo. Histological analysis indicated that chondrocytes grown on dead cartilage matrix produced new matrix that integrated individual cartilage pieces with mechanically functional tissue.     

张力刺激对关节软骨细胞β-肌动蛋白mRNA表达的影响

目的 观察张力刺激对关节软骨细胞β-肌动蛋白(β-aetin)mRNA表达的影响.方法 分别获取正常和骨关节炎关节软骨细胞,给予3%、6%和15%的张力刺激,运用实时定量PCR方法检测不同张力刺激强度下关节软骨细胞β-actin mRNA表达的变化.结果 6%和15%的张力刺激均可明显提高lE常关节软骨细胞β-actinmRNA表达(1.34±0.05,1.36±0.04,P＜0.05),而只有15%的张力刺激才能明显增加骨关节炎关节软骨细胞β-actin mRNA表达.结论 关节软骨细胞β-actin mRNA表达量随张力刺激强度不同而变化,不同内外环境使关节软骨细胞对张力刺激的反应不同,故在其相关生物力学研究中不能应用β-actin作为内参.     

Confocal microscopy indentation system for studying in situ chondrocyte mechanics

Chondrocytes synthesize extracellular matrix molecules, thus they are essential for the development, adaptation and maintenance of articular cartilage. Furthermore, it is well accepted that the biosynthetic activity of chondrocytes is influenced by the mechanical environment. Therefore, their response to mechanical stimuli has been studied extensively. Much of the knowledge in this area of research has been derived from testing of isolated cells, cartilage explants, and fixed cartilage specimens: systems that differ in important aspects from chondrocytes embedded in articular cartilage and observed during loading conditions. In this study, current model systems have been improved by working with the intact cartilage in real time. An indentation system was designed on a confocal microscope that allows for simultaneous loading and observation of chondrocytes in their native environment. Cell mechanics were then measured under precisely controlled loading conditions. The indentation system is based on a light transmissible cylindrical glass indentor of 0.17 mm thickness and 1.64 mm diameter that is aligned along the focal axis of the microscope and allows for real time observation of live cells in their native environment. The system can be used to study cell deformation and biological responses, such as calcium sparks, while applying prescribed loads on the cartilage surface. It can also provide novel information on the relationship between cell loading and cartilage adaptive/degenerative processes in the intact tissue.     

Cell-based bonding of articular cartilage: An extended study

This study evaluated the biomechanical characteristics of newly formed cartilaginous tissue synthesized from isolated chondrocytes and seeded onto devitalized cartilage in an extended study in vivo. Cartilage from porcine articular joints was cut into regular discs and devitalized by multiple freeze-thaw cycles. Articular chondrocytes were enzymatically isolated and incubated in suspension culture in the presence of devitalized cartilage discs for 21 days. This procedure allowed the isolated chondrocytes to adhere to the devitalized matrix surfaces. Chondrocyte-matrix constructs were assembled with fibrin glue and implanted in dorsal subcutaneous pockets in nude mice for up to 8 months. Histological evaluation and biomechanical testing were performed to quantify the integration of cartilage pieces and the mechanical properties of the constructs over time. Histological analysis indicated that chondrocytes grown on devitalized cartilage discs produced new matrix that bonded and integrated individual cartilage elements with mechanically functional tissue. Biomechanical testing demonstrated a time dependent increase in tensile strength, failure strain, failure energy, and tensile modulus to values 5-30% of normal articular cartilage by 8 months in vivo. The values recorded at 4 months were not statistically different from those collected at the latest time point, indicating that the limits of the biomechanical property values were reached after four months from implantation.     

Organisation of the chondrocyte cytoskeleton and its response to changing mechanical conditions in organ culture

Articular cartilage undergoes cycles of compressive loading during joint movement, leading to its cyclical deformation and recovery. This loading is essential for chondrocytes to perform their normal function of maintenance of the extracellular matrix. Various lines of evidence suggest the involvement of the cytoskeleton in load sensing and response. The purpose of the present study is to describe the 3-dimensional (3D) architecture of the cytoskeleton of chondrocytes within their extracellular matrix, and to examine cytoskeletal responses to experimentally varied mechanical conditions. Uniformly sized explants of articular cartilage were dissected from adult rat femoral heads. Some were immediately frozen, cryosectioned and labelled for filamentous actin using phalloidin, and for the focal contact component vinculin or for vimentin by indirect immunofluorescence. Sections were examined by confocal microscopy and 3D modelling. Actin occurred in all chondrocytes, appearing as bright foci at the cell surface linked to an irregular network beneath the surface. Cell surface foci colocalised with vinculin, suggesting the presence of focal contacts between the chondrocyte and its pericellular matrix. Vimentin label occurred mainly in cells of the deep zone. It had a complex intracellular distribution, with linked networks of fibres surrounding the nucleus and beneath the plasma membrane. When cartilage explants were placed into organ culture, where in the absence of further treatments cartilage imbibes fluid from the culture medium and swells, cytoskeletal changes were observed. After 1 h in culture the vimentin cytoskeleton was disassembled, leading to diffuse labelling of cells. After a further hour in culture filamentous vimentin label reappeared in deep zone chondrocytes, and then over the next 48 h became more widespread in cells of the explants. Actin distribution was unaffected by culture. Further experiments were performed to test the effects of load on the cytoskeleton. Explants were placed in culture and immediately subjected to static uniaxial radially unconfined compressive loads of 0.5, 1, 2 or 4 MPa for 1 h using a pneumatic loading device. Loads greater than 0.5 MPa maintained the vimentin organisation over the culture period. At 0.5 MPa, the chondrocytes within the explant behaved as in free-swelling culture. The rapid change in vimentin organisation probably relates to rapid swelling of the explants—under free-swelling conditions, these reached their maximum swollen size in just 15 min of culture. The chondrocytes' response to change in tissue dimensions, and thus to their relationship to their immediate environment, was to disassemble their vimentin networks. Loading probably counteracts the swelling pressure of the tissue. Overall, this work suggests that chondrocytes maintain their actin cytoskeleton and modify their vimentin cytoskeleton in response to changing mechanical conditions.     

Three-dimensional tissue engineering of hyaline cartilage: comparison of adult nasal and articular chondrocytes

Adult chondrocytes are less chondrogenic than immature cells, yet it is likely that autologous cells from adult patients will be used clinically for cartilage engineering. The aim of this study was to compare the postexpansion chondrogenic potential of adult nasal and articular chondrocytes. Bovine or human chondrocytes were expanded in monolayer culture, seeded onto polyglycolic acid (PGA) scaffolds, and cultured for 40 days. Engineered cartilage constructs were processed for histological and quantitative analysis of the extracellular matrix and mRNA. Some engineered constructs were implanted in athymic mice for up to six additional weeks before analysis. Using adult bovine tissues as a cell source, nasal chondrocytes generated a matrix with significantly higher fractions of collagen type II and glycosaminoglycans as compared with articular chondrocytes. Human adult nasal chondrocytes proliferated approximately four times faster than human articular chondrocytes in monolayer culture, and had a markedly higher chondrogenic capacity, as assessed by the mRNA and protein analysis of in vitro-engineered constructs. Cartilage engineered from human nasal cells survived and grew during 6 weeks of implantation in vivo whereas articular cartilage constructs failed to survive. In conclusion, for adult patients nasal septum chondrocytes are a better cell source than articular chondrocytes for the in vitro engineering of autologous cartilage grafts. It remains to be established whether cartilage engineered from nasal cells can function effectively when implanted at an articular site.     

Biosynthetic response of passaged chondrocytes in a type II collagen scaffold to mechanical compression

To investigate the potential utility of mechanical loading in articular cartilage tissue engineering, porous type II collagen scaffolds seeded with adult canine passaged chondrocytes were subjected to static and dynamic compressions of varying magnitudes (0-50% static strain) and durations (1-24 h), and at different times during culture (2-30 days postseeding). The effects of mechanical compression on the biosynthetic activity of the chondrocytes were evaluated by measuring the amount of (3)H-proline-labeled proteins and (35)S-sulfate-labeled proteoglycans that accumulated in the cell-scaffold construct and was released to the medium during the loading period. Similar to published results on loading of articular cartilage explants, static compression decreased protein and proteoglycan biosynthesis in a time- and dose-dependent manner (each p < 0.005), and selected dynamic compression protocols were able to increase rates of biosynthesis (p < 0.05). The main difference between the results seen for this tissue engineering system and cartilage explants was in the amount of newly synthesized matrix molecules that accumulated within the construct under dynamic loading, with less accumulating in the type II collagen scaffold. In summary, the general biosynthetic response of passaged chondrocytes in the porous type II collagen scaffolds is similar to that seen for chondrocytes in their native environment. Future work needs to be directed to modifications of the cell-seeded construct to allow for the capture of the newly synthesized matrix molecules by the scaffold.     

Surface motion upregulates superficial zone protein and hyaluronan production in chondrocyte-seeded three-dimensional scaffolds

A cartilage engineering bioreactor has been developed that provides joint-specific kinematics. This study investigated the effect of articular motion on the gene expression of superficial zone protein (SZP) and hyaluronan synthases (HASs) and on the release of SZP and hyaluronan of chondrocytes seeded onto biodegradable scaffolds. Cylindrical (8 x 4 mm) porous polyurethane scaffolds were seeded with bovine articular chondrocytes and subjected to static or dynamic compression, with and without articulation against a ceramic hip ball. After loading, the mRNA expression of SZP and HASs was analyzed, and SZP immunoreactivity and hyaluronan concentration of conditioned media were determined. Surface motion significantly upregulated the mRNA expression of SZP and HASs. Axial compression alone had no effect on SZP and increased HAS mRNA only at high strain amplitude. SZP was immunodetected only in the media of constructs exposed to surface motion. The release of hyaluronan into the culture medium was significantly enhanced by surface motion. These results indicate that specific stimuli that mimic the kinematics of natural joints, such as articular motion, may promote the development of a functional articular surface-synovial interface.     

Effects of perfusion and dynamic loading on human neocartilage formation in alginate hydrogels

Dynamic loading and perfusion culture environments alone are known to enhance cartilage extracellular matrix (ECM) production in dedifferentiated articular chondrocytes. In this study, we explored whether a combination of these factors would enhance these processes over a free-swelling (FS) condition using adult human articular chondrocytes embedded in 2% alginate. The alginate constructs were placed into a bioreactor for perfusion (P) only (100?μL/per minute) or perfusion and dynamic compressive loading (PL) culture (20% for 1?h, at 0.5?Hz), each day. Control FS alginate gels were maintained in six-well static culture. Gene expression analysis was conducted on days 7 and 14, while cell viability, immunostaining, and mechanical property testing were performed on day 14 only. Total glycosaminoglycan (GAG) content and GAG synthesis were assessed after 14 days. Col2a1 mRNA expression levels were significantly higher (at least threefold; p<0.05) in both bioreactor conditions compared with FS by days 7 and 14. For all gene studies, no significant differences were seen between P and PL treatments. Aggrecan mRNA levels were not significantly altered in any condition although both GAG/DNA and (35)S GAG incorporation studies indicated higher GAG retention and synthesis in the FS treatment. Collagen type II protein deposition was low in all samples, link protein distribution was more diffuse in FS condition, and aggrecan deposition was located in the outer regions of the alginate constructs in both bioreactor conditions, yet more uniformly in the FS condition. Catabolic gene expression (matrix metalloproteinase 3 [MMP3] and inducible nitric oxide synthase [iNOS]) was higher in bioreactor conditions compared with FS, although iNOS expression levels decreased to approximately fourfold less than the FS condition by day 14. Our data indicate that conditions created in the bioreactor enhanced both anabolic and catabolic responses, similar to other loading studies. Perfusion was sufficient alone to promote this dual response. PL increased the deposition of aggrecan surrounding cells compared with the other conditions; however, overall low GAG retention in the bioreactor system was likely due to both perfusion and catabolic conditions created. Optimal conditions, which permit appropriate anabolic and catabolic processes for accumulation of ECM and tissue remodeling for neocartilage development, specifically for humans, are needed.     

Differences between sub-populations of cultured bovine articular chondrocytes. I. Morphology and cartilage matrix production

Bovine articular chondrocytes cultured in agarose gel comprise a heterogeneous population when judged by morphological and histochemical criteria. The purpose of the present experiments was to compare, under the same conditions of culture, sub-populations of chondrocytes derived from different depths of articular cartilage. Sub-populations of chondrocytes were cultured separately following their isolation from slices of articular cartilage cut from successive depths of the tissue. Chondrocytes derived from superficial and deep zones differed significantly in morphology, rate of proliferation, and activity in secreting a proteoglycan-rich extracellular matrix. The differences are sufficient to account for the heterogeneity observed in cultures of the entire cell population, and the correlate well with known variations with depth in morphology and histochemistry of intact articular cartilage. These results demonstrate that articular chondrocytes continue in culture to express metabolic differences which reflect their original anatomical location; such differences may have important functional significance.     

Immunohistochemical detection of estrogen receptor alpha in articular chondrocytes from cows, pigs and humans: in situ and in vitro results.

Clinical observations suggest that estrogens are involved in the pathogenesis of postmenopausal osteoarthritis, but only little is known about the influence of these hormones on articular cartilage cells. The effect of estradiol is mediated by estrogen receptors alpha and beta. The goal of the present study was to search for estrogen receptor alpha in articular tissue from cows, pigs and humans by immunohistochemistry to form a basis for in vitro studies. In addition, we also tried to detect estrogen receptor alpha in cultivated articular chondrocytes from cows and bulls under certain culture conditions. Estrogen receptor alpha is detected by the use of antibody 13H2 in articular chondrocytes from cows, bulls, pigs and humans. Chondrocytes are physiologically exposed to reduced oxygen tension. In isolated articular chondrocytes from cows and bulls incubated either with 21% O2 or with 5% O2 positive cells were also found. These positive results therefore encourage testing the influence of estradiol on cultivated articular cartilage cells in these species under different culture conditions.     

A high throughput perfusion-based microbioreactor platform integrated with pneumatic micropumps for three-dimensional cell culture

This study reports a new perfusion-based, micro three-dimensional (3-D) cell culture platform for high-throughput cell culture using enabling microfluidic technologies. In this work, the micro 3-D cell culture platform is fabricated based on SU-8 lithography and polydimethylsiloxane replication processes. The micro cell culture platform can maintain homogenous and stable culture environments, as well as provide pumping of multiple mediums and efficient cell/agarose (scaffold) loading functions, which allows realization of more precise and high-throughput cell culture-based assays. In this study, the design of a high-throughput medium pumping mechanism was especially highlighted. A new serpentine-shaped pneumatic micropump was used to provide the required medium pumping mechanism. Pneumatic microchannels with a varied length and U-shape bending corners were designed to connect three rectangular pneumatic chambers such that one can fine-tune the pumping rate of the S-shape micropump by using the fluidic resistance. To achieve a high-throughput medium pumping function, a pneumatic tank was designed to simultaneously activate all of the 30 pneumatic micropumps with a uniform pumping rate. Results show that the pumping rates of the 30 integrated micropumps were statistically uniform with a flow rate ranging from 8.5 to 185.1 μl h^-1, indicating the present multiple medium pumping mechanism is feasible for high-throughput medium delivery purposes. Furthermore, as a demonstration case study, 3-D culture of oral cancer cell was successfully performed, showing that the cell viability remained as high as 95% - 98% during the 48 h cell culture. As the result of miniaturization, this perfusion-based 3-D cell culture platform not only provides a well-defined and stable culture condition, but also greatly reduces the sample/reagent consumption and the need for human intervention. Moreover, due to the integrated capability for multiple medium pumping, high-throughput research work can be achieved. These traits are found particularly useful for high-precision and high-throughput, 3-D cell culture-based assay.     

Mechanisms underlying the synergistic enhancement of self-assembled neocartilage treated with chondroitinase-ABC and TGF-β1

Developing a platform for in vitro cartilage formation would enhance the study of cartilage development, pathogenesis, and regeneration. To improve neocartilage formation, our group developed a novel self-assembly process for articular chondrocytes, which has been improved in this study using a novel combination of catabolic and anabolic agents. TGF-β1 was applied in conjunction with the enzyme chondroitinase-ABC (C-ABC) to additively increase tensile properties and synergistically enhance collagen content. Additionally, microarray analysis indicated that TGF-β1 up-regulated MAPK signaling in contrast to C-ABC, which did not enrich genetic pathways. The lack of genetic signaling spurred investigation of the biophysical role of C-ABC, which showed that C-ABC treatment increased collagen fibril diameter and density. After four weeks of culture in nude mice, neocartilage exhibited stability and maturation. This study illustrated an innovative strategy for improving in vitro and in vivo articular cartilage formation and elucidated mechanisms underlying TGF-β1 and C-ABC treatment.     

Clonal populations of chondrocytes with progenitor properties identified within human articular cartilage

The aim of the present study was to identify and characterize progenitor properties of human articular chondrocytes selected by using agarose suspension culture. In this chondrogenic selective culture condition, about 3.6% of seeded surplus chondrocytes from patients undergoing articular chondrocyte transplantation proliferated and formed cell clusters after 6 weeks. Phase-contrast microscopy and transmission electron microscopy revealed four different types of cell clusters differing in cellular content and matrix production. Based on their morphological features, they were named the homogenous (H), the homogenous matrix (HM), the differentiated matrix (DM) and the differentiated (D) cell clusters. All cell clusters showed positive safranin O staining, and matrix was positive for antibodies detecting type II collagen and aggrecan. The clusters were further demonstrated to express the genes for fibroblast growth factor receptor 3, type IIA collagen and type IIB collagen, while type X collagen was not expressed. After subcloning, the H and HM clusters demonstrated the best proliferative capacity. Chondrocytes from these two cell clusters also showed phenotypic plasticity in chondrogenic, adipogenic as well as osteogenic assays. This study demonstrates that existing subpopulations of cells with chondroprogenitor properties can be isolated from human adult articular cartilage using agarose suspension cultures.     

Development of a biocomposite to fill out articular cartilage lesions. Light, scanning and transmission electron microscopy of sheep chondrocytes cultured on a collagen I/III sponge

The regenerative capacity of hyaline articular cartilage is limited. Thus, lesions of this tissue are a proarthrotic factor, and up to now the conservative treatment of cartilage lesions and arthrosis does not yield satisfying results. Therefore, autologous transplantation of articular chondrocytes is being investigated in a variety of different assays. The aim of our study was to create a mechanically stable cell-matrix implant with viable and active chondrocytes which could serve to fill out articular lesions created in the knees of sheep. For this purpose, articular cartilage was collected from knee lesions, chondrocytes were liberated enzymatically and seeded in culture flasks and cultured till confluency. Cells were then trypsinized and grown on a type I/III collagen matrix (Chondro-Gide™, Geistlich Biomaterials, Wolhusen, Switzerland) for 3, 6 and 10 days before being fixed and embedded for electron microscopy by routine methods. Scanning electron microscopy was performed after dehydration in acetone, critical point drying and sputter-coating with gold-paladium.

Light microscopically, clusters of chondrocytes can be seen on the surface of the matrix with a few cells growing into the matrix. Transmission electron microscopic photographs yield a rather differentiated chondrocyte-like appearance, which is evidence of a matrix-induced redifferentiation after dedifferentiation during the growth period in the culture flasks. Scanning electron microscopic results show large, flattened chondrocytes without signs of differentiation on plastic, whereas chondrocytes grown on the Chondro-Gide™ sponge show a more roundish aspect wrapping firmly around the collagen fibrils, exhibiting numerous contacts with the matrix. This cell-matrix biocomposite can now serve to fill out articular cartilage lesions created in the knees of sheep.     

The use of growth factors in the proliferation of avian articular chondrocytes in a serum-free culture system

The purpose of this research was to develop a serum-free culture system for the proliferation of articular chondrocytes. Various growth factors and hormones were tested for their ability to stimulate avian articular chondrocyte proliferation in a defined, serum-free media. Multiple members of the fibroblast growth factor (FGF) family (FGFs: 2, 4, and 9), insulin-like growth factor-1 (IGF-1) and transforming growth factor beta (TGF-beta) significantly stimulated H-thymidine uptake by chondrocytes grown in an adherent serum-free, culture system. Double or triple combinations of these mitogenic growth factors further stimulated cell proliferation to levels that were equivalent to, or surpassed those of cells grown in serum. Although proliferation was maximally stimulated, chondrocytes grown in the presence of FGF-2, IGF-1, and TGF-beta, began to exhibit changes in morphology and collagen II expression declined. This culture system could be used to rapidly expand a population of articular chondrocytes prior to transferring these cells to a non-adherent culture system, which could then stabilize the chondrocyte phenotype and maximize matrix synthesis and integrity.     

Human platelet supernatant promotes proliferation but not differentiation of articular chondrocytes

The objective of the study was to evaluate the growth-promoting activity of human platelet supernanant on primary chondrocytes in comparison with fetal calf serum (FCS) supplemented cell culture medium. Furthermore, the differentiation potential of platelet supernatant was determined in three-dimensional artificial cartilage tissues of bovine articular chondrocytes. Proliferation of articular and nasal septal chondrocytes was assayed by incorporation of BrdU upon stimulation with ten different batches of human platelet supernatant. On bovine articular chondrocytes, all these batches were at least as growth-promoting as FCS. On nasal septal chondrocytes, nine out of ten batches revealed increased or equivalent mitogenic stimulation compared with medium supplemented with FCS. Three-dimensional culture and subsequent histological analysis of matrix formation were used to determine the differentiation properties of platelet supernatant on articular chondrocytes. Human platelet supernatant failed to induce the deposition of typical cartilage matrix components, whereas differentiation and matrix formation were apparent upon cultivation of articular chondrocytes with FCS. Proliferation assays demonstrated that human platelet supernatant stimulates growth of articular and nasal septal chondrocytes; however, platelet supernatant failed to stimulate articular chondrocytes to redifferentiate in three-dimensional chondrocyte cultures. Therefore platelet lysate may be suitable for chondrocyte expansion, but not for maturation of tissue-engineered cartilage.