Department of Trauma Surgery, AUVA Trauma Center Meidling, Kundratstrasse 37, Vienna, A-1120, Austria.
Medical Department II-VINFORCE Study Group, St. Vincent Hospital, Academic Teaching Hospital of the Medical University of Vienna, Stumpergasse 13, Vienna, A-1060, Austria.
J Orthop Res. 2019 Dec;37(12):2516-2523. doi: 10.1002/jor.24442. Epub 2019 Aug 26.
Bone stress injuries are commonly due to repetitive loading, as often described in competitive athletes or military recruits. The underlying pathophysiology of bone stress injuries is multifactorial. The present cross-sectional study investigated (i) cortical and trabecular bone microstructure as well as volumetric bone mineral density in subjects with bone stress injuries at the tibial diaphysis, measured at the distal tibia and the distal radius by means of high-resolution peripheral quantitative computed tomography (CT), (ii) areal bone mineral density using dual-energy X-ray absorptiometry as well as calcaneal dual X-ray absorptiometry and laser, and (iii) the influence on bone turnover markers of formation and resorption at the early phase after injury. A total of 26 Caucasian male professional soldiers with post-training bone stress injury at the tibial diaphysis were included (case group). A total of 50 male, Caucasian professional soldiers from the same military institution served as controls (control group). High-resolution peripheral quantitative CT revealed a higher total area at the radius within the case group. Cortical bone mineral density was reduced at the radius and tibia within the case group. The trabecular number and trabecular thickness were reduced at the tibia in the case group. The trabecular network was more inhomogeneous at the radius and tibia within the case group. Calcaneal dual X-ray absorptiometry and laser was significantly reduced in the case group. This study quantified differences in bone microstructure among otherwise healthy individuals. Differences in bone microarchitecture may impair the biomechanical properties by increasing the susceptibility to sustain bone stress injuries. © 2019 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 37:2516-2523, 2019.
骨应力性损伤通常是由于反复加载引起的,这种情况在竞技运动员或新兵中较为常见。骨应力性损伤的潜在病理生理学是多因素的。本横断面研究调查了(i)胫骨骨干骨应力损伤患者胫骨远端和桡骨远端的高分辨率外周定量 CT 测量的皮质和小梁骨微观结构以及体积骨矿物质密度,(ii)双能 X 线吸收法和跟骨双 X 线吸收法和激光测量的面积骨矿物质密度,以及(iii)骨转换标志物形成和吸收在损伤后早期对骨转换标志物的影响。共纳入 26 名白人男性职业军人,胫骨骨干训练后出现骨应力性损伤(病例组)。来自同一军事机构的 50 名白人男性职业军人作为对照组(对照组)。高分辨率外周定量 CT 显示病例组桡骨总面积较高。病例组桡骨和胫骨的皮质骨矿物质密度降低。病例组胫骨的小梁数量和小梁厚度减少。病例组的小梁网络在桡骨和胫骨处更为不均匀。跟骨双 X 线吸收法和激光检查显示病例组明显减少。本研究量化了健康个体之间骨微观结构的差异。骨微结构的差异可能通过增加发生骨应力性损伤的易感性而损害生物力学特性。©2019 矫形研究协会。由 Wiley Periodicals, Inc. 出版。J Orthop Res 37:2516-2523, 2019.
