Abstract
Substantial evidence from animal studies indicates that jumping increases bone mass and strength. However, most studies have focused on the take-off, rather than the landing phase of jumps. Thus, we compared the effects of landing and upward jump impact on trabecular bone mass and microarchitecture. Male Wistar rats aged 10 weeks were randomly assigned to the following groups: sedentary control (CON), 40-cm upward jumps (40UJ); 40-cm drop jumps (40DJ); and 60-cm drop jumps (60DJ) (n = 10 each). The upward jump protocol comprised 10 upward jumps/day, 5 days/week for 8 weeks to a height of 40 cm. The drop jump protocol comprised dropping rats from a height of 40 or 60 cm at the same frequency and time period as the 40UJ group. Trabecular bone mass, architecture, and mineralization at the distal femoral metaphysis were evaluated using microcomputed tomography. Ground reaction force (GRF) was measured using a force platform. Bone mass was significantly higher in the 40UJ group compared with the DJ groups (+49.1% and +28.3%, respectively), although peak GRF (−57.8% and −122.7%, respectively) and unit time force (−21.6% and −36.2%, respectively) were significantly lower in the 40UJ group. These results showed that trabecular bone mass in growing rats is increased more effectively by the take-off than by the landing phases of jumps and suggest that mechanical stress accompanied by muscle contraction would be more important than GRF as an osteogenic stimulus. However, the relevance of these findings to human bone physiology is unclear and requires further study.
Highlights
Exercise is considered one of the best strategies for enhancing bone mass and strength, not all types of exercise are beneficial
After one week of acclimation to the diet and new environment, the rats were randomly assigned to the following groups (n = 10 per group): sedentary controls reared in the breeding cage (CON), rats that jumped upwards to a height of 40 cm (40UJ), and rats that fell from a height of 40 (40DJ) or 60 (60DJ) cm
Values are shown as means 6 SD. n, number of rats in each group; CON, sedentary control group reared in breeding cage; 40-cm drop jumps (40DJ), rats that jumped downwards from a height of 40 cm; 60-cm drop jumps (60DJ), rats that jumped downwards from a height of 60 cm; 40-cm upward jumps (40UJ), rats that jumped upwards to a height of 40 cm. doi:10.1371/journal.pone.0107953.t001
Summary
Exercise is considered one of the best strategies for enhancing bone mass and strength, not all types of exercise are beneficial. Among various types of exercise in rats, high-impact loading such as jumping seems to be most beneficial for increasing bone mass and strength rather than lowimpact loading such as running [1,2,3]. Landing impact is considered more beneficial for building bone mass and increasing strength than take-off impact. The effects of landing (free-fall landing) on bone mass and strength have been investigated in growing rats [7,8,9]. Welch et al [9] showed that free-fall landing imparts greater osteogenic effects to the bones of the forelimb than the hindlimb in rats [1]. Their report suggested that the type of landing could increase bone mass more effectively than take-off, but the effects of the two jump phases have not been directly compared in the same bone
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