基于定量计算机断层扫描的前屈时椎体强度预测
Quantitative computed tomography-based predictions of vertebral strength in anterior bending.
作者信息
Buckley Jenni M, Cheng Liu, Loo Kenneth, Slyfield Craig, Xu Zheng
机构信息
Department of Mechanical Engineering, University of California-Berkeley, Berkeley, CA, USA.
出版信息
Spine (Phila Pa 1976). 2007 Apr 20;32(9):1019-27. doi: 10.1097/01.brs.0000260979.98101.9c.
STUDY DESIGN
This study examined the ability of QCT-based structural assessment techniques to predict vertebral strength in anterior bending.
OBJECTIVE
The purpose of this study was to compare the abilities of QCT-based bone mineral density (BMD), mechanics of solids models (MOS), e.g., bending rigidity, and finite element analyses (FE) to predict the strength of isolated vertebral bodies under anterior bending boundary conditions.
SUMMARY OF BACKGROUND DATA
Although the relative performance of QCT-based structural measures is well established for uniform compression, the ability of these techniques to predict vertebral strength under nonuniform loading conditions has not yet been established.
METHODS
Thirty human thoracic vertebrae from 30 donors (T9-T10, 20 female, 10 male; 87 +/- 5 years of age) were QCT scanned and destructively tested in anterior bending using an industrial robot arm. The QCT scans were processed to generate specimen-specific FE models as well as trabecular bone mineral density (tBMD), integral bone mineral density (iBMD), and MOS measures, such as axial and bending rigidities.
RESULTS
Vertebral strength in anterior bending was poorly to moderately predicted by QCT-based BMD and MOS measures (R2 = 0.14-0.22). QCT-based FE models were better strength predictors (R2 = 0.34-0.40); however, their predictive performance was not statistically different from MOS bending rigidity (P > 0.05).
CONCLUSIONS
Our results suggest that the poor clinical performance of noninvasive structural measures may be due to their inability to predict vertebral strength under bending loads. While their performance was not statistically better than MOS bending rigidities, QCT-based FE models were moderate predictors of both compressive and bending loads at failure, suggesting that this technique has the potential for strength prediction under nonuniform loads. The current FE modeling strategy is insufficient, however, and significant modifications must be made to better mimic whole bone elastic and inelastic material behavior.
研究设计
本研究检测了基于定量计算机断层扫描(QCT)的结构评估技术预测前屈时椎体强度的能力。
目的
本研究旨在比较基于QCT的骨密度(BMD)、固体力学模型(MOS)(如弯曲刚度)和有限元分析(FE)预测在前屈边界条件下孤立椎体强度的能力。
背景数据总结
尽管基于QCT的结构测量在均匀压缩方面的相对性能已得到充分证实,但这些技术在非均匀加载条件下预测椎体强度的能力尚未得到证实。
方法
对来自30名捐赠者的30个人类胸椎(T9 - T10,20名女性,10名男性;年龄87±5岁)进行QCT扫描,并使用工业机器人手臂在前屈状态下进行破坏性测试。对QCT扫描结果进行处理,以生成特定标本的FE模型以及小梁骨密度(tBMD)、整体骨密度(iBMD)和MOS测量值,如轴向和弯曲刚度。
结果
基于QCT的BMD和MOS测量对前屈时椎体强度的预测效果较差至中等(R2 = 0.14 - 0.22)。基于QCT的FE模型是更好的强度预测指标(R2 = 0.34 - 0.40);然而,其预测性能与MOS弯曲刚度在统计学上无差异(P > 0.05)。
结论
我们的结果表明非侵入性结构测量的临床性能不佳可能是由于它们无法预测弯曲载荷下的椎体强度。虽然它们的性能在统计学上并不优于MOS弯曲刚度,但基于QCT的FE模型是压缩和弯曲载荷失效时的中等预测指标,表明该技术在非均匀载荷下具有强度预测潜力。然而,当前的FE建模策略并不充分,必须进行重大修改以更好地模拟全骨的弹性和非弹性材料行为。
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