Xiphoid process-derived chondrocytes: a novel cell source for elastic cartilage regeneration.

Reconstruction of elastic cartilage requires a source of chondrocytes that display a reliable differentiation tendency. Predetermined tissue progenitor cells are ideal candidates for meeting this need; however, it is difficult to obtain donor elastic cartilage tissue because most elastic cartilage serves important functions or forms external structures, making these tissues indispensable. We found vestigial cartilage tissue in xiphoid processes and characterized it as hyaline cartilage in the proximal region and elastic cartilage in the distal region. Xiphoid process-derived chondrocytes (XCs) showed superb in vitro expansion ability based on colony-forming unit fibroblast assays, cell yield, and cumulative cell growth. On induction of differentiation into mesenchymal lineages, XCs showed a strong tendency toward chondrogenic differentiation. An examination of the tissue-specific regeneration capacity of XCs in a subcutaneous-transplantation model and autologous chondrocyte implantation model confirmed reliable regeneration of elastic cartilage regardless of the implantation environment. On the basis of these observations, we conclude that xiphoid process cartilage, the only elastic cartilage tissue source that can be obtained without destroying external shape or function, is a source of elastic chondrocytes that show superb in vitro expansion and reliable differentiation capacity. These findings indicate that XCs could be a valuable cell source for reconstruction of elastic cartilage.

Chondrocyte-biocompatibility of DegraPol-foam: in vitro evaluations.

Histological and biochemical investigations were carried out in order to evaluate the chondrocyte compatibility of a recently developed biodegradable polyesterurethane-foam (DegraPol-foam). Therefore, cell adhesion, cell growth, and the preservation of chondrocyte phenotype was measured in rat xyphoid chondrocytes seeded on DegraPol-foam. Chondrocytes, isolated from xyphoids of adult male rats, exhibited relatively high cell adhesion on DegraPol-foam (about 60% of that found on TCPS). Scanning electron microscopy (SEM) showed that chondrocytes grew on the surface and into the open cell pores of the foam. Morphologically, cells found on the surface of the foam exhibited a flat cell appearance and built a confluent cell multilayer. In contrast, the interior of the foam cells showed rounded morphology in cell aggregates and cell islets. In addition, chondrocytes proliferated on the DegraPol-foam (doubling-time of about 12.5 days) and preserved their phenotype for up to 14 days. Compared to freshly isolated chondrocytes, cells seeded on the foam produced high concentrations of collagen type II for up to 2 weeks: the ratio of type II/I collagen was 1.2-1.4 fold higher than the ratio found in freshly isolated cells. No significant difference was observed in chondroitin sulfate levels produced by freshly isolated cells and cells cultured on DegraPol-foam for up to 14 days. To sum up, our results indicate that DegraPol-foam is a compatible substrate for chondrocytes.