Kayanja Mark M, Ferrara Lisa A, Lieberman Isador H
Spine Research Laboratory, Department of Orthopaedics, Cleveland Clinic Foundation, 9500 Euclid Avenue, Cleveland, OH 44195, USA.
Spine J. 2004 Jan-Feb;4(1):76-87. doi: 10.1016/j.spinee.2003.07.003.
Vertebral compression fractures (VCFs) are a common clinical problem and may follow trauma or be pathological. Osteoporosis increases susceptibility to fracture by reducing bone mass and weakening bone architecture. Approximately 2.5 million osteoporotic fractures occur worldwide annually, usually involving the vertebrae, wrist and hip. In the United States 700,000 VCFs occur annually, causing significant morbidity, mortality and economic burden. An initial VCF often leads to subsequent VCFs. The strain distribution along the anterior cortex, the major load-bearing pathway in flexion, may be predictive of impending VCF. Regions of high strain distribution are likely to experience secondary fracture.
To investigate the distribution of anterior cortical strain at, above and below an experimentally created index VCF to determine the vertebral body at risk of secondary fracture.
In vitro experimental study using cadaveric thoracic spinal segments.
Seventeen thoracic spines underwent dual-energy X-ray absorptiometry (DEXA) to assess bone mineral density and were divided into T1-T3 (Subsegment 1), T4-T6 (Subsegment 2), T7-T9 (Subsegment 3) and T10-T12 (Subsegment 4). Rectangular rosette strain gauges were applied to the anterior cortices of the vertebrae of each subsegment (vertebrae in each specimen were denoted V1-superior, V2-intermediate and V3-inferior). V1 and V3 were partially embedded into polyester resin blocks, which were used to mount the specimens in a materials testing machine. Nondestructive predefect testing was performed in compression at 125 N and 250 N, followed by flexion at 1.25 Nm and 2.5 Nm. To ensure fracture reproducibility, V2 of each specimen had a trabecular defect created to a volume of 21.3+/-4.4% of the V2 centrum. Postdefect nondestructive compression and flexion were then performed in a manner similar to the predefect tests, followed by destructive testing in flexion. Anterior cortical shear strain on V1, V2 and V3, applied moments and applied flexion angle were all measured and analyzed.
A VCF occurred in 55 of the 59 subsegments. Fifty-one VCF (93%) were seen in V2 and 4 VCF (7%) were seen in V1. After the creation of the trabecular defect, the shear strain on V2 increased, but a comparison of the postdefect with the predefect nondestructive tests showed no significant differences. The pre- and postdefect shear strain distribution in compression and flexion was V1strain>V3strain>V2strain. Shear strain at failure was highest on V2, and in all subsegments there were significant differences between V2 and V3 (p<.05). In all subsegments there were no significant differences between V2 and V1 (p>.05) at failure with the exception of Subsegment 1 where V2 and V1 were significantly different (p<.05). The predominant strain pattern at failure was (V2strain>V1strain>V3strain V2strain>>V3strain). Using shear strain as the codeterminant of peak moment with bending stiffness and applied angle at failure, the strain on V1 was the greatest predictor (p=.0084; R2=0.78). These findings suggest that the events leading to a secondary fracture probably start before the index VCF occurs and continue with loading beyond the index VCF.
Anterior cortical strain is concentrated at the apex of a thoracic kyphotic curve. The vertebral body immediately above the index VCF has the next highest amount of strain and therefore the highest risk of secondary fracture.
椎体压缩骨折(VCF)是常见的临床问题,可由创伤引起或为病理性骨折。骨质疏松症通过降低骨量和削弱骨结构增加骨折易感性。全球每年约发生250万例骨质疏松性骨折,通常累及椎体、腕部和髋部。在美国,每年发生70万例VCF,造成显著的发病率、死亡率和经济负担。初次VCF常导致后续VCF。沿前皮质的应变分布是屈曲时的主要承重路径,可能预示即将发生的VCF。高应变分布区域可能会发生二次骨折。
研究实验性创建的索引VCF上方、下方及处的前皮质应变分布,以确定有二次骨折风险的椎体。
使用尸体胸段脊柱节段进行体外实验研究。
对17个胸段脊柱进行双能X线吸收法(DEXA)评估骨密度,并分为T1 - T3(亚段1)、T4 - T6(亚段2)、T7 - T9(亚段3)和T10 - T12(亚段4)。将矩形应变片应用于每个亚段椎体的前皮质(每个标本中的椎体分别标记为V1 - 上位、V2 - 中位和V3 - 下位)。V1和V3部分嵌入聚酯树脂块中,用于将标本安装在材料试验机上。在125 N和250 N压缩力下进行无损预缺陷测试,随后在1.25 Nm和2.5 Nm弯曲力下进行测试。为确保骨折可重复性,每个标本的V2制造一个小梁缺损,缺损体积为V2椎体的21.3±4.4%。然后以与预缺陷测试类似的方式进行缺陷后无损压缩和弯曲测试,随后进行弯曲破坏测试。测量并分析V1、V2和V3上的前皮质剪切应变、施加的力矩和施加的弯曲角度。
59个亚段中有55个发生了VCF。51个VCF(93%)发生在V2,4个VCF(7%)发生在V1。创建小梁缺损后,V2上的剪切应变增加,但缺陷后与缺陷前无损测试的比较显示无显著差异。压缩和弯曲时缺陷前后的剪切应变分布为V1应变>V3应变>V2应变。破坏时V2上的剪切应变最高,所有亚段中V2和V3之间均有显著差异(p<0.05)。除亚段1中V2和V1有显著差异(p<0.05)外,所有亚段破坏时V2和V1之间均无显著差异(p>0.05)。破坏时的主要应变模式为(V2应变>V1应变>V3应变,V2应变>>V3应变)。使用剪切应变作为峰值力矩与弯曲刚度和破坏时施加角度的共同决定因素,V1上的应变是最大预测因子(p = 0.0084;R2 = 0.78)。这些发现表明,导致二次骨折的事件可能在索引VCF发生之前就已开始,并在超过索引VCF的加载过程中持续。
前皮质应变集中在胸段后凸曲线的顶点。索引VCF上方紧邻的椎体应变次之,因此二次骨折风险最高。
