sepharose and Hypertrophy

Joint-derived stem cells are a promising alternative cell source for cartilage repair therapies that may overcome many of the problems associated with the use of primary chondrocytes (CCs). The objective of this study was to compare the in vitro functionality and in vivo phenotypic stability of cartilaginous tissues engineered using bone marrow-derived stem cells (BMSCs) and joint tissue-derived stem cells following encapsulation in agarose hydrogels. Culture-expanded BMSCs, fat pad-derived stem cells (FPSCs), and synovial membrane-derived stem cells (SDSCs) were encapsulated in agarose and maintained in a chondrogenic medium supplemented with transforming growth factor-β3. After 21 days of culture, constructs were either implanted subcutaneously into the back of nude mice for an additional 28 days or maintained for a similar period in vitro in either chondrogenic or hypertrophic media formulations. After 49 days of in vitro culture in chondrogenic media, SDSC constructs accumulated the highest levels of sulfated glycosaminoglycan (sGAG) (∼2.8% w/w) and collagen (∼1.8% w/w) and were mechanically stiffer than constructs engineered using other cell types. After subcutaneous implantation in nude mice, sGAG content significantly decreased for all stem cell-seeded constructs, while no significant change was observed in the control constructs engineered using primary CCs, indicating that the in vitro chondrocyte-like phenotype generated in all stem cell-seeded agarose constructs was transient. FPSCs and SDSCs appeared to undergo fibrous dedifferentiation or resorption, as evident from increased collagen type I staining and a dramatic loss in sGAG content. BMSCs followed a more endochondral pathway with increased type X collagen expression and mineralization of the engineered tissue. In conclusion, while joint tissue-derived stem cells possess a strong intrinsic chondrogenic capacity, further studies are needed to identify the factors that will lead to the generation of a more stable chondrogenic phenotype.

Topics: Adipose Tissue; Animals; Bone Marrow Cells; Cartilage; Chondrocytes; Chondrogenesis; Collagen; Culture Media; Elastic Modulus; Glycosaminoglycans; Hypertrophy; Mice; Mice, Inbred BALB C; Mice, Nude; Phenotype; Sepharose; Staining and Labeling; Stem Cells; Sus scrofa; Synovial Membrane; Tissue Engineering

Regeneration of the osteochondral interface is critical for integrative and functional cartilage repair. This study focuses on the design and optimization of a hydrogel-ceramic composite scaffold of agarose and hydroxyapatite (HA) for calcified cartilage formation. The first study objective was to compare the effects of HA on non-hypertrophic and hypertrophic chondrocytes cultured in the composite scaffold. Specifically, cell growth, biosynthesis, hypertrophy, and scaffold mechanical properties were evaluated. Next, the ceramic phase of the scaffold was optimized in terms of particle size (200 nm vs. 25 μm) and dose (0-6 w/v%). It was observed that while deep zone chondrocyte (DZC) biosynthesis and hypertrophy remained unaffected, hypertrophic chondrocytes measured higher matrix deposition and mineralization potential with the addition of HA. Most importantly, higher matrix content translated into significant increases in both compressive and shear mechanical properties. While cell hypertrophy was independent of ceramic size, matrix deposition was higher only with the addition of micron-sized ceramic particles. In addition, the highest matrix content, mechanical properties and mineralization potential were found in scaffolds with 3% micro-HA, which approximates both the mineral aggregate size and content of the native interface. These results demonstrate that the biomimetic hydrogel-ceramic composite is optimal for calcified cartilage formation and is a promising design strategy for osteochondral interface regeneration.

Topics: Animals; Biomechanical Phenomena; Cartilage, Articular; Cattle; Cell Proliferation; Cell Size; Chondrocytes; Durapatite; Hypertrophy; Particle Size; Regeneration; Sepharose; Tissue Scaffolds

Sternal chondrocytes of 17-day-old chick embryos in serum-free agarose culture secrete transforming growth factor-beta. Media conditioned by such cells prevent serum-induced chondrocyte hypertrophy and cause a phenotypic modulation in serum-free culture which is similar to that observed for chondrocytes in monolayer culture. The modulated cells lose the round shape of differentiated chondrocytes and increasingly with time resemble tendon fibroblasts embedded into agarose. In addition, they produce less matrix macromolecules which include collagen I rather than cartilage collagens II, IX, X, and XI. All of these effects are abolished upon addition to the conditioned media of a monoclonal antibody against recombinant human transforming growth factor-beta 2. The same factor caused effects closely similar to those elicited by conditioned media. Therefore, the phenotypic modulation in adhesion-dependent cultures of chondrocytes in vitro does not directly result from cell-matrix interactions but can be produced also in suspension culture under the direction of appropriate diffusible stimuli that include transforming growth factor-beta. In addition, the results support the concept of transforming growth factor-beta as a multifunctional cytokine acting differently on cells of the same developmental origin depending on their stage of differentiation.

Topics: Animals; Cartilage; Cell Differentiation; Cells, Cultured; Chick Embryo; Collagen; Culture Media, Serum-Free; Hypertrophy; Phenotype; Recombinant Proteins; Sepharose; Sternum; Transforming Growth Factor beta