胸椎在轴向压缩与屈曲时的相对强度。

Relative strength of thoracic vertebrae in axial compression versus flexion.

作者信息

Buckley Jenni M, Kuo Calvin C, Cheng Liu C, Loo Kenneth, Motherway Julie, Slyfield Craig, Deviren Vedat, Ames Christopher

机构信息

Biomechanical Testing Facility, UCSF/SFGH Orthopaedic Trauma Institute, University of California, San Francisco, CA 94110, USA.

出版信息

Spine J. 2009 Jun;9(6):478-85. doi: 10.1016/j.spinee.2009.02.010. Epub 2009 Apr 11.

DOI:10.1016/j.spinee.2009.02.010

PMID:19364678

Abstract

BACKGROUND CONTEXT

Noninvasive strength assessment techniques are the clinical standard in the diagnosis and treatment of osteoporotic vertebral fractures, and the efficacy of these protocols depends on their ability to predict vertebral strength at all at-risk spinal levels under multiple physiological loading conditions.

PURPOSE

To assess differences in vertebral strength between loading modes and across spinal levels.

STUDY DESIGN/SETTING: This study examined the relative strength of isolated vertebral bodies in compression versus flexion.

METHODS

Destructive biomechanical tests were conducted on 30 pairs of donor-matched, isolated thoracic vertebral bodies (T9 and T10; F=19, M=11; 87+5 years old, max=97 years old, min=80 years old) in both uniform axial compression and flexion using previously described protocols. Quantitative computed tomography (QCT) scans were taken before mechanical testing and used to obtain bone mineral density (BMD) and "mechanics of solids" (MOS) measures, such as axial and bending rigidities.

RESULTS

Compressive strength was higher than flexion strength for each donor by 940+152N (p<.001, paired t test), and vertebral strengths in the two loading modes were moderately correlated (adjusted R(2)=0.50, p<.001). For both compression and flexion loading modes, adjacent-level BMD and MOS metrics had approximately half the predictive capacity as same-level measurements, and BMD and MOS values were only moderately correlated across spinal levels.

CONCLUSIONS

The results of this study are important in designing clinical test protocols for assessing vertebral fracture risk. Because vertebral body flexion and compressive strength are not strongly correlated and flexion strength is significantly less than compressive strength, it is imperative to investigate a patient's spinal structural capacity under bending loading conditions. Furthermore, our work suggests that clinicians using QCT-based measures should perform site-specific strength assessments on each at-risk spinal level. Future work should focus on improving the accuracy of densitometric measures in predicting vertebral strength in flexion and also on examining same- versus adjacent-level strength assessment for radiographic techniques with lower X-ray dosage, such as dual-energy X-ray absorptiometry.

摘要

背景

非侵入性强度评估技术是骨质疏松性椎体骨折诊断和治疗的临床标准，这些方案的有效性取决于它们在多种生理负荷条件下预测所有高危脊柱节段椎体强度的能力。

目的

评估不同加载模式和不同脊柱节段之间的椎体强度差异。

研究设计/设置：本研究考察了孤立椎体在压缩和屈曲状态下的相对强度。

方法

采用先前描述的方案，对30对供体匹配的孤立胸椎椎体（T9和T10；女性19例，男性11例；年龄87±5岁，最大97岁，最小80岁）进行了均匀轴向压缩和屈曲状态下的破坏性生物力学测试。在机械测试前进行定量计算机断层扫描（QCT），并用于获取骨密度（BMD）和“固体力学”（MOS）测量值，如轴向和弯曲刚度。

结果

每个供体的压缩强度比屈曲强度高940±152N（p<0.001，配对t检验），两种加载模式下的椎体强度呈中度相关（调整后R²=0.50，p<0.001）。对于压缩和屈曲加载模式，相邻节段的BMD和MOS指标的预测能力约为同节段测量值的一半，且BMD和MOS值在不同脊柱节段之间仅呈中度相关。

结论

本研究结果对于设计评估椎体骨折风险的临床试验方案具有重要意义。由于椎体的屈曲强度和压缩强度相关性不强，且屈曲强度明显低于压缩强度，因此有必要研究患者在弯曲负荷条件下的脊柱结构能力。此外，我们的研究表明，使用基于QCT测量的临床医生应对每个高危脊柱节段进行特定部位的强度评估。未来的工作应集中在提高密度测量法预测椎体屈曲强度的准确性，以及研究低X线剂量的放射学技术（如双能X线吸收法）的同节段与相邻节段强度评估。

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胸椎在轴向压缩与屈曲时的相对强度。

Relative strength of thoracic vertebrae in axial compression versus flexion.

作者信息

机构信息

出版信息

BACKGROUND CONTEXT

PURPOSE

METHODS

RESULTS

CONCLUSIONS

背景

目的

方法

结果

结论

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