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男性跑步者、体操运动员、游泳运动员和非运动员对照组的骨横截面积几何形状:一项髋关节结构分析研究。

Bone cross-sectional geometry in male runners, gymnasts, swimmers and non-athletic controls: a hip-structural analysis study.

机构信息

Carnegie Research Institute, Leeds Metropolitan University, Headingley Campus, Leeds, LS6 3QS, UK.

出版信息

Eur J Appl Physiol. 2012 Feb;112(2):535-41. doi: 10.1007/s00421-011-2008-y. Epub 2011 May 24.

DOI:10.1007/s00421-011-2008-y
PMID:21607679
Abstract

Loading of the skeleton is important for the development of a functionally and mechanically appropriate bone structure, and can be achieved through impact exercise. Proximal femur cross-sectional geometry was assessed in the male athletes (n = 55) representing gymnastics, endurance running and swimming, and non-athletic controls (n = 22). Dual energy X-ray absorptiometry (iDXA, GE Healthcare, UK) measurements of the total body (for body composition) and the left proximal femur were obtained. Advanced hip structural analysis (AHA) was utilised to determine the areal bone mineral density (aBMD), hip axis length (HAL), cross-sectional area (CSA), cross-sectional moment of inertia (CSMI) and the femoral strength index (FSI). Gymnasts and runners had greater age, height and weight adjusted aBMD than in swimmers and controls (p < 0.05). Gymnasts and runners had greater resistance to axial loads (CSA) and the runners had increased resistance against bending forces (CSMI) compared to swimmers and controls (p < 0.01). Controls had a lower FSI compared to gymnasts and runners (1.4 vs. 1.8 and 2.1, respectively, p < 0.005). Lean mass correlated with aBMD, CSA and FSI (r = 0.365-0.457, p < 0.01), particularly in controls (r = 0.657-0.759, p < 0.005). Skeletal loading through the gymnastics and running appears to confer a superior bone geometrical advantage in the young adult men. The importance of lean body mass appears to be of particular significance for non-athletes. Further characterisation of the bone structural advantages associated with different sports would be of value to inform the strategies directed at maximising bone strength and thus, preventing fracture.

摘要

骨骼的加载对于形成功能和机械上适当的骨结构非常重要,可以通过冲击运动来实现。评估了代表体操、耐力跑和游泳的男性运动员(n = 55)和非运动员对照组(n = 22)的股骨近端横截面积。使用双能 X 射线吸收法(iDXA,GE Healthcare,英国)测量全身(用于身体成分)和左侧股骨近端。利用先进的髋关节结构分析(AHA)来确定面积骨矿物质密度(aBMD)、髋关节轴长(HAL)、横截面积(CSA)、横截面对惯性矩(CSMI)和股骨强度指数(FSI)。与游泳运动员和对照组相比,体操运动员和跑步运动员的年龄、身高和体重调整后的 aBMD 更高(p < 0.05)。与游泳运动员和对照组相比,体操运动员和跑步运动员对抗轴向负荷(CSA)的能力更强,跑步运动员对抗弯曲力(CSMI)的能力更强(p < 0.01)。与体操运动员和跑步运动员相比,对照组的 FSI 较低(分别为 1.4、1.8 和 2.1,p < 0.005)。瘦体重与 aBMD、CSA 和 FSI 相关(r = 0.365-0.457,p < 0.01),特别是在对照组中(r = 0.657-0.759,p < 0.005)。通过体操和跑步进行的骨骼加载似乎为年轻成年男性提供了更好的骨骼几何优势。瘦体重的重要性对于非运动员来说似乎尤为重要。进一步描述与不同运动相关的骨结构优势将有助于制定旨在最大限度地提高骨强度从而预防骨折的策略。

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