Diederichs Gerd, Link Thomas M, Kentenich Marie, Schwieger Karsten, Huber Markus B, Burghardt Andrew J, Majumdar Sharmila, Rogalla Patrik, Issever Ahi S
Department of Radiology, Charité - Universitätsmedizin Berlin, Charité Campus Mitte, Berlin, Germany.
Bone. 2009 May;44(5):976-83. doi: 10.1016/j.bone.2009.01.372. Epub 2009 Jan 31.
The prediction of bone strength can be improved when determining bone mineral density (BMD) in combination with measures of trabecular microarchitecture. The goal of this study was to assess parameters of trabecular bone structure and texture of the calcaneus by clinical multi-detector row computed tomography (MDCT) in an experimental in situ setup and to correlate these parameters with microCT (microCT) and biomechanical testing. Thirty calcanei in 15 intact cadavers were scanned using three different protocols on a 64-slice MDCT scanner with an in-plane pixel size of 208 microm and 500 microm slice thickness. Bone cores were harvested from each specimen and microCT images with a voxel size of 16 microm were obtained. After image coregistration, trabecular bone structure and texture were evaluated in identical regions on the MDCT images. After data acquisition, uniaxial compression testing was performed. Significant correlations between MDCT- and microCT-derived measures of bone volume fraction (BV/TV), trabecular thickness (Tb.Th) and trabecular separation (Tb.Sp) were found (range, R(2)=0.19-0.65, p<0.01 or 0.05). The MDCT-derived parameters of volumetric BMD, app. BV/TV, app. Tb.Th and app. Tb.Sp were capable of predicting 60%, 63%, 53% and 25% of the variation in bone strength (p<0.01). When combining those measures with one additional texture index (either GLCM, TOGLCM or MF.euler), prediction of mechanical competence was significantly improved to 86%, 85%, 71% and 63% (p<0.01). In conclusion, this study showed the feasibility of trabecular microarchitecture assessment using MDCT in an experimental setup simulating the clinical situation. Multivariate models of BMD or structural parameters combined with texture indices improved prediction of bone strength significantly and might provide more reliable estimates of fracture risk in patients.
在结合小梁微结构测量值来测定骨矿物质密度(BMD)时,骨强度的预测可得到改善。本研究的目的是通过临床多排螺旋计算机断层扫描(MDCT)在实验原位设置中评估跟骨小梁骨结构和纹理的参数,并将这些参数与显微CT(microCT)和生物力学测试相关联。使用三种不同方案在具有208微米平面像素大小和500微米层厚的64排MDCT扫描仪上扫描15具完整尸体中的30个跟骨。从每个标本中获取骨芯,并获得体素大小为16微米的microCT图像。在图像配准后,在MDCT图像上的相同区域评估小梁骨结构和纹理。在数据采集后,进行单轴压缩测试。发现MDCT和microCT得出的骨体积分数(BV/TV)、小梁厚度(Tb.Th)和小梁间距(Tb.Sp)测量值之间存在显著相关性(范围,R(2)=0.19 - 0.65,p<0.01或0.05)。MDCT得出的体积BMD、表观BV/TV、表观Tb.Th和表观Tb.Sp参数能够预测骨强度变化的60%、63%、53%和25%(p<0.01)。当将这些测量值与一个额外的纹理指数(GLCM、TOGLCM或MF.euler)相结合时,机械性能的预测显著提高到86%、85%、71%和63%(p<0.01)。总之,本研究表明在模拟临床情况的实验设置中使用MDCT评估小梁微结构的可行性。BMD或结构参数与纹理指数的多变量模型显著改善了骨强度的预测,并可能为患者骨折风险提供更可靠的估计。
