Experiments were carried out to investigate the influence of loading velocity on the stiffness of the articular cartilage matrix. Compression tests were conducted on cartilage alone and cartilage-on-bone at strain-rates ranging from 10(-5)sec-1 to 10(3)sec-1 and it was established that matrix stiffness increased progressively in the "low" and "medium" strain-rate regimens and assumes a limiting value at "high" rates of loading up to impact. Analysis of the strain field characteristics associated with the compression process, both at low and high velocities, suggests that two fundamentally different mechanisms of deformation control the development of cartilage matrix stiffness. At low strain-rates a consolidation-dependent stiffness occurs while at high strain rates the high stiffness results from a classical elastic deformation process. This bifurcation in the tissue's response to loading is likely to affect the redistribution of joint contact stresses being transmitted into the subchondral bone.
This study uses a bovine patella model to compare the relative merits of on-bone compliance and thickness measurements, free-swelling behaviour, and structural imaging with differential interference contrast (DIC) light microscopy to assess the biomechanical normality of the cartilage matrix. The results demonstrate that across a spectrum of cartilage tissues from immature, mature, through to mildly degenerate, and all with intact articular surfaces, there is a consistent pattern of increased free swelling of the isolated general matrix with age and degeneration.High swelling was always associated with major structural alterations of the general matrix that were readily imaged using DIC light microscopy. Conversely, for all tissue groups, no relationship was observed between thickness vs. compliance and compliance vs. general matrix swelling. Only in the proximal aspects of the normal mature and degenerate tissues was there a correlation between thickness and general matrix swelling. Free-swelling measurements combined with fibrillar texture imaging using DIC light microscopy are therefore recommended as providing a reliable and quick method of assessing the biomechanical condition of the cartilage general matrix.
Cartilage-on-bone samples were dynamically and statically compressed at various stress levels to determine the deformation and rupture behaviour of the articular surface (AS). Instantaneous deformations were captured photographically by using a transparent indenter in combination with a ultra high speed flash. Principal strains (PS) were evaluated using large deformation theory. The tensile strains induced indirectly in the AS were a function of the rate at which the direct compressive force was applied. At the same compressive stress the tensile strains induced statically were approximately twice those induced dynamically. Rupture of the AS occurred in about 60%) of those specimens tested statically at 15 MPa and followed approximately the split-line direction. By contrast, no rupture was observed dynamically even at stresses as high as 28 MPa. In terms of joint function the research demonstrates that the AS is considerably more resistant to rupture under dynamic than under static loading. The biomechanical parameter governing rupture appears to be the level of indirectly induced surface strain rather than the directly applied compressive stress. The very different mechanisms controlling the compressive deformation of articular cartilage (AC) at high vs low rates of loading clearly influence the levels of in-plane strain induced in the AS. 0
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