Time, stress, and location dependent chondrocyte death and collagen damage in cyclically loaded articular cartilage

We investigated the effect of light (0.1 MPa), moderate (1 MPa) or heavy (5 MPa) cyclical stresses applied continuously or intermittently for 0 to 72 h on cell death and collagen damage in adult bovine cartilage explants. No increase in cell death was observed in the cartilage loaded with a continuous cyclic stress at 0.1 MPa for up to 72 h. Cell death occurred in the uppermost superficial tangential zone (STZ) of explants after loading for 1 h at 1 MPa, and reached a maximum depth of 61 ± 23 μm by 6 h (at the rate of 9 ± 6 μm/h). At 5 MPa, cell death occurred in the STZ after as little as 1 min (30 cycles) of loading, and reached a maximum depth of 70 ± 2 μm by 60 min (47 ± 8 μm/h). When an intermittent (with 2 s on, 2 s off) stress of 5 MPa was applied, cell death appeared in the STZ after 2 min (30 cycles) and increased to a depth of 63 ± 2 μm at 60 min (45 ± 11 μm/h). No significant differences were observed between the continuous and intermittent loading conditions. Both collagenase‐cleaved and denatured collagen fibers were found in the STZ of explants loaded at 1 and 5 MPa. We concluded that load‐induced cell death depends on load duration and magnitude, and that the chondrocytes in the STZ are more vulnerable to load‐induced injury than those in the middle and deep zones. © 2003 Orthopaedic Research Society. Published by Elsevier Science Ltd. All rights reserved.

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