Articular cartilage has poor repair potential and the tissue formed is mechanically incompetent. Mesenchymal stromal cells (MSCs) show chondrogenic properties and the ability to re-grow cartilage, however a viable human model for testing cartilage regeneration and repair is lacking. Here, we describe an Human femoral heads (FHs) were obtained following femoral neck fracture with ethical permission/patient consent and full-depth cartilage wells made using a 3mm biopsy punch. Pancreas-derived mesenchymal stromal cells (P-MSC) were prepared in culture media at ~5000 cells/20µl and added to each well and leakage prevented with fibrin sealant. After 24hrs, the sealant was removed and medium replaced with StemProTM chondrogenesis differentiation medium. The FHs were incubated (37oC;5% CO2) for 3wks, followed by a further 3wks in standard medium with 10% human serum with regular medium changes throughout. Compared to wells with medium only, A-MSCs produced a thin film across the wells which was excised en-block, fixed with 4% paraformaldehyde and frozen for cryo-sectioning. The cell/tissue films varied in thickness ranging over 20-440µm (82±21µm; mean±SEM; N=3 FHs). The thickness of MSC films abutting the cartilage wells was variable but generally greater (15-1880µm) than across the wells, suggesting an attachment to native articular cartilage. Staining of the films using safranin O (for glycosaminoglycans; quantified using ImageJ) was variable (3±8%; mean±SEM; N=3) but in one experiment reached 20% of the adjacent cartilage. A preliminary assessment of the repair tissue gave an O'Driscoll score of 10/24 (24 is best). These preliminary results suggest the Supported by the CSO (TCS/17/32).
Human articular cartilage chondrocytes undergo changes to their morphology and clustering with cartilage degeneration as occurs in osteoarthritis(1). The consequences of chondrocyte de-differentiation on mechanically-resilient extracellular matrix metabolism are, however, unclear. We have assessed whether there is a relationship between abnormal chondrocyte morphology, as demonstrated by the presence of cytoplasmic processes, and chondrocyte clustering, with cell-associated type-I collagen during cartilage degeneration. The femoral heads of 9 patients were obtained (with Ethical permission/consent) following hip replacement surgery and cartilage areas graded (Grade-0 non-degenerate; Grade-1 mildly degenerate). Abstract
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The development of promising therapeutics for cartilage repair/regeneration have been hampered by the inadequacy of existing animal models and lack of suitable translational Fifteen fresh, viable human femoral heads were obtained from 15 patients (with ethical permission/consent) undergoing hemiarthroplasty for hip fracture, and cultured aseptically (37°C) for up to 10wks. Culture conditions included static/stirred standard media (Dulbecco's modified Eagle's medium; DMEM) and supplementation with 10% human serum (HS). Chondrocyte viability, density, cell morphology, cell volume, glycosaminoglycan(GAG)/collagen content, surface roughness and cartilage thickness were quantified over time.Abstract
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