Depth-dependent compressive properties of normal aged human femoral head articular cartilage: relationship to fixed charge density

OBJECTIVES

Determine the depth-varying confined and osmotic compression moduli of normal human articular cartilage from the femoral head, and test whether these moduli are dependent on fixed charge density.

METHODS AND RESULTS

Using an automated instrument to allow epifluorescence microscopy analysis during confined compression testing on cartilage samples, the equilibrium confined compression modulus (H(A 0)) was found to vary markedly with depth (z=0-1500 microm) from the articular surface. H(A 0) increased from 1.16+/-0.20 MPa in the superficial (0-125 microm) layer to 7.75+/-1.45 MPa in the deepest (1250-1500 microm) layer tested, and was fit by the expression, H(A 0)(z) [MPa]=1.44 exp(0.0012.z [microm]). Also, in successive slices of cartilage extending from the articular surface to the middle-deep regions, the bulk modulus (K(0)) and fixed charge density (FCD) increased, consistent with previous findings. While H(A 0), K(0), and FCD each varied with depth from the articular surface, the dependence of H(A 0) and K(0) on depth did not appear to be completely related to variations in FCD.

CONCLUSIONS

The confined compression modulus of normal aged human femoral head articular cartilage increases markedly with depth from the articular surface, a trend similar to that observed for articular cartilage from other joints in animals but with an absolute amplitude that is several-fold higher. The compressive properties were not simply related to FCD at different depths from the articular surface, suggesting that other as yet undefined factors also contribute to compressive properties.

Mechanical compression modulates proliferation of transplanted chondrocytes

The presence of an appropriate number of reparative cells in an articular cartilage defect is probably necessary for consistent and successful repair. Following the transplantation of chondrocytes into a defect, cell proliferation may modulate local defect cellularity. Transplanted cells can be compressed during cartilage repair as a result of joint-loading or press-fitting a graft into a cartilage defect. The objective of this study was to characterize the proliferative response of chondrocytes after attachment to cartilage and application of static compressive stress between cartilaginous surfaces in an ex vivo model. The chondrocytes were isolated from adult bovine cartilage, cultured in high-density monolayer, resuspended, and then transplanted onto the surface of devitalized cartilage at a density of 250,000 cells/cm2. The total DNA content of transplanted cell layers increased steadily to a plateau by 5 days and represented a 4-fold increase in cell number during incubation in medium including serum and ascorbate. Over the culture period, the level of DNA synthesis ([3H]thymidine incorporation), on a per cell basis, decreased steadily (88% between days 0 and 6). The application of 24 hours of static compressive stress (0.06-0.4 MPa) to the adherent cells at 1 and 4 days after transplantation inhibited overall DNA synthesis by 70-approximately 87% compared with unloaded controls. After release from load, cell proliferation generally remained at low levels. The marked proliferation of chondrocytes when attached to cartilage without applied load and the inhibition of this proliferation by relatively low-amplitude static compressive stress may be relevant to the occasional overgrowth of tissue in some chondrocyte transplantation procedures. The dosimetry of these effects suggests that the in vivo mechanical environment may have a marked effect on proliferation of transplanted chondrocytes.