Injuries in elite and recreational snowboarders.

BACKGROUND: The relatively young sport of snowboarding exhibits high injury rates. The current efforts to characterise the injury pattern of snowboarders focus largely on the general snowboard population and upper extremity injuries, the most common injury site in snowboarders as a whole. METHODS: In an effort to describe the current published information available on snowboarding injuries in the elite-level population, a literature search was performed and the articles related to snowboarding injuries were analysed. Additionally, the literature pertaining to biomechanical analyses of injury and injury prevention was included. RESULTS: Studies rarely stratify the snowboarders by skill level, a classification which has a profound effect on the riding activities of snowboarders and the resultant injury patterns. Elite-level snowboarders are often injured when performing difficult manoeuvres at high velocities and with amplified levels of force to the lower limbs. Consequently, elite-level snowboarders suffer from injuries that are of higher severity and have decidedly greater lower extremity injury rates. Conversely, injuries to the upper extremities are decreased in the elite snowboarders. Furthermore, little has been published regarding the biomechanical analyses and injury prevention for the protection of the lower extremities in snowboarding. CONCLUSIONS: Snowboarding continues to evolve as a sport. This includes a steady progression in the degree of difficulty of the manoeuvres conducted by athletes and an increase in the number of snowboarders attempting such manoeuvres. The injury patterns across the skill levels are markedly different, and it is imperative that the research directed towards understanding the disparate lower extremity injury pattern of elite-level snowboarders is increased.

Heterogeneity of tibial plateau cartilage in response to a physiological compressive strain rate.

Knowledge of the extent to which tibial plateau cartilage displays non-uniform mechanical topography under physiologically relevant loading conditions is critical to evaluating the role of biomechanics in knee osteoarthritis. Cartilage explants from 21 tibial plateau sites of eight non-osteoarthritic female cadaveric knees (age: 41-54; BMI: 14-20) were tested in unconfined compression at 100% strain/s. The elastic tangent modulus at 10% strain (E(10%) ) was calculated for each site and averaged over four geographic regions: not covered by meniscus (I); covered by meniscus-anterior (II); covered by meniscus-exterior (III); and covered by meniscus-posterior (IV). A repeated-measures mixed model analysis of variance was used to test for effects of plateau, region, and their interaction on E(10%) . Effect sizes were calculated for each region pair. E(10%) was significantly different (p<0.05) for all regional comparisons, except I-II and III-IV. The regional pattern of variation was consistent across individuals. Moderate to strong effect sizes were evident for regional comparisons other than I-II on the lateral side and III-IV on both sides. Healthy tibial cartilage exhibits significant mechanical heterogeneity that manifests in a common regional pattern across individuals. These findings provide a foundation for evaluating the biomechanical mechanisms of knee osteoarthritis.