Low-oxygen conditions promote synergistic increases in chondrogenesis during co-culture of human osteoarthritic stem cells and chondrocytes.

There has been increased interest in co-cultures of stem cells and chondrocytes for cartilage tissue engineering as there are the limitations associated with using either cell type alone. Drawbacks associated with the use of chondrocytes include the limited numbers of cells available for isolation from damaged or diseased joints, their dedifferentiation during in vitro expansion, and a diminished capacity to synthesise cartilage-specific extracellular matrix components with age and disease. This has motivated the use of adult stem cells with either freshly isolated or culture-expanded chondrocytes for cartilage repair applications; however, the ideal combination of cells and environmental conditions for promoting robust chondrogenesis remains unclear. In this study, we compared the effect of combining a small number of freshly isolated or culture-expanded human chondrocytes with infrapatellar fat pad-derived stem cells (FPSCs) from osteoarthritic donors on chondrogenesis in altered oxygen (5% or 20%) and growth factor supplementation (TGF-β3 only or TGF-β3 and BMP-7) conditions. Both co-cultures, but particularly those including freshly isolated chondrocytes, were found to promote cell proliferation and enhanced matrix accumulation compared to the use of FPSCs alone, resulting in the development of a tissue that was compositionally more similar to that of the native articular cartilage. Local oxygen levels were found to impact chondrogenesis in co-cultures, with more robust increases in proteoglycan and collagen deposition observed at 5% O2 . Additionally, collagen type I synthesis was suppressed in co-cultures maintained at low-oxygen conditions. This study demonstrates that a co-culture of freshly isolated human chondrocytes and FPSCs promotes robust chondrogenesis and thus is a promising cell combination for cartilage tissue engineering.