与基于骨量（双能X线吸收法）相比，定量计算机断层扫描（pQCT）基于几何结构的参数和定量超声（QUS）的材料参数能否更好地预测桡骨强度？

Can geometry-based parameters from pQCT and material parameters from quantitative ultrasound (QUS) improve the prediction of radial bone strength over that by bone mass (DXA)?

作者信息

Hudelmaier M, Kuhn V, Lochmüller E M, Well H, Priemel M, Link T M, Eckstein F

机构信息

Musculoskeletal Research Group, Institute of Anatomy, LMU München, Pettenkoferstrasse 11, 80336, Munich, Germany.

出版信息

Osteoporos Int. 2004 May;15(5):375-81. doi: 10.1007/s00198-003-1551-8. Epub 2004 Jan 22.

DOI:10.1007/s00198-003-1551-8

PMID:14740151

Abstract

The diagnosis of osteoporosis is generally based on the assessment of bone mineral content with dual X-ray absorptiometry (DXA) but does not account for the spatial distribution and inherent material properties of the tissue. Peripheral quantitative computed tomography (pQCT) permits one to measure the compartment-specific density and geometry-based parameters of cortical bone. Quantitative ultrasound (QUS) parameters are associated with material properties of cortical bone. The purpose of this study was to test the hypothesis that pQCT and cortical QUS provide additional information to DXA in predicting structural strength of the distal radius. The intact right arm and the isolated left radius were harvested from 70 formalin-fixed cadavers (age 79+/-11 years). The bone mineral content (BMC) was assessed with DXA at the radial metaphysis and shaft. pQCT was also used at the metaphysis and the shaft, while QUS was employed only at the shaft. The failure loads of the radius were assessed by use of a 3-point bending test (isolated radius) and a complex fall simulation (intact arm). The BMC (DXA) displayed a correlation of r=0.96 with the failure moments in 3-point bending ( P<0.001). The correlation between failure load and geometry-based parameters (pQCT) ranged from r=0.85 to r=0.96 and was r=0.64 for the speed of sound (QUS) ( P <0.001). Cortical thickness (pQCT) improved the prediction marginally (r=0.964) in combination with DXA. For the fall simulation, the correlation coefficients were r=0.76 for BMC (DXA) of the shaft, r=0.83 for metaphyseal bone content (pQCT), r=0.55 for QUS, and ranged from r=0.59 to r=0.74 for geometry-based parameters at the shaft (pQCT). pQCT and QUS parameters provided no significant improvement versus DXA alone. Measurement of bone mass by DXA or pQCT thus appears to be sufficient as a surrogate of mechanical strength and fracture risk of the distal radius.

摘要

骨质疏松症的诊断通常基于双能X线吸收法（DXA）对骨矿物质含量的评估，但未考虑组织的空间分布和固有材料特性。外周定量计算机断层扫描（pQCT）可用于测量皮质骨特定区域的密度和基于几何形状的参数。定量超声（QUS）参数与皮质骨的材料特性相关。本研究的目的是检验以下假设：在预测桡骨远端的结构强度方面，pQCT和皮质QUS能为DXA提供额外信息。从70具用福尔马林固定的尸体（年龄79±11岁）上取下完整的右臂和分离的左桡骨。在桡骨干骺端和骨干处用DXA评估骨矿物质含量（BMC）。在干骺端和骨干处也使用pQCT，而仅在骨干处采用QUS。通过三点弯曲试验（分离的桡骨）和复杂跌倒模拟（完整手臂）评估桡骨的破坏载荷。BMC（DXA）与三点弯曲试验中的破坏力矩的相关性为r = 0.96（P < 0.001）。破坏载荷与基于几何形状的参数（pQCT）之间的相关性范围为r = 0.85至r = 0.96，与声速（QUS）的相关性为r = 0.64（P < 0.001）。皮质厚度（pQCT）与DXA联合使用时，对预测的改善作用微乎其微（r = 0.964）。对于跌倒模拟，骨干的BMC（DXA）的相关系数为r = 0.76，干骺端骨含量（pQCT）为r = 0.83，QUS为r = 0.55，骨干处基于几何形状的参数（pQCT）的相关系数范围为r = 0.59至r = 0.74。与单独使用DXA相比，pQCT和QUS参数没有显著改善。因此，用DXA或pQCT测量骨量似乎足以作为桡骨远端机械强度和骨折风险的替代指标。

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与基于骨量（双能X线吸收法）相比，定量计算机断层扫描（pQCT）基于几何结构的参数和定量超声（QUS）的材料参数能否更好地预测桡骨强度？

Can geometry-based parameters from pQCT and material parameters from quantitative ultrasound (QUS) improve the prediction of radial bone strength over that by bone mass (DXA)?

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