Abstract
Cartilage metabolism—both the synthesis and breakdown of cartilage constituents and architecture—is influenced by its mechanical loading. Therefore, physical activity is often recommended to maintain cartilage health and to treat or slow the progression of osteoarthritis, a debilitating joint disease causing cartilage degeneration. However, the appropriate exercise frequency, intensity, and duration cannot be prescribed because direct in vivo evaluation of cartilage following exercise has not yet been performed. To address this gap in knowledge, we developed a cartilage stress test to measure the in vivo strain response of healthy human subjects’ tibial cartilage to walking exercise. We varied both walk duration and speed in a dose-dependent manner to quantify how these variables affect cartilage strain. We found a nonlinear relationship between walk duration and in vivo compressive strain, with compressive strain initially increasing with increasing duration, then leveling off with longer durations. This work provides innovative measurements of cartilage creep behavior (which has been well-documented in vitro but not in vivo) during walking. This study showed that compressive strain increased with increasing walking speed for the speeds tested in this study (0.9–2.0 m/s). Furthermore, our data provide novel measurements of the in vivo strain response of tibial cartilage to various doses of walking as a mechanical stimulus, with maximal strains of 5.0% observed after 60 minutes of walking. These data describe physiological benchmarks for healthy articular cartilage behavior during walking and provide a much-needed baseline for studies investigating the effect of exercise on cartilage health.
Highlights
Cartilage metabolism is related to the mechanical loading of the tissue because chondrocytes, the cells responsible for maintaining cartilage architecture, are mechanically sensitive[1,2,3,4,5,6,7]
Exercise is often recommended as a potential treatment for osteoarthritis (OA), a disabling disease of synovial joints that results in cartilage degeneration[2]
In controlled trials of exercise intervention for OA, physical activity has resulted in decreased pain scores[15,16], decreased disability scores[15,16], and increased glycosaminoglycan content as measured by delayed gadolinium-enhanced magnetic resonance imaging[17]
Summary
Cartilage metabolism is related to the mechanical loading of the tissue because chondrocytes, the cells responsible for maintaining cartilage architecture, are mechanically sensitive[1,2,3,4,5,6,7]. Cartilage displays creep behavior[21,22,23], in which the strain increases over time Leveraging this time-dependent (viscoelastic) response of cartilage to mechanical load[24], our laboratory has recently developed a new technique for investigating cartilage strain in vivo[18] using three dimensional (3D) modeling and magnetic resonance imaging (MRI). We quantified the effects of varying durations and speeds on the in vivo response of cartilage following walking exercise to develop a cartilage stress test in a dose-dependent manner This investigation provides important insight into normal in vivo cartilage biomechanics under varying intensities of loading, which has important implications for OA progression, prevention, and treatment.
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