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OSTEOPOROTIC VERTEBRAL FRACTURES ARE INFLUENCED BY ABNORMAL LOAD-SHARING IN ELDERLY SPINES



Abstract

Introduction: Age-related hormonal changes and inactivity lead to systemic bone loss and osteoporotic fractures. However, it is not clear why the vertebral body should be affected so often, or why its anterior region should characteristically sustain a “wedge” deformity. We hypothesise that intervertebral disc degeneration in elderly spines leads to altered spinal load-sharing in such a manner that the anterior region of the vertebral body becomes vulnerable to injury.

Methods: Forty thoraco-lumbar “motion segments”, consisting of two vertebrae and the intervening disc and ligaments, were obtained from cadaver spines aged 62–94 yrs. Volumetric bone mineral density (BMD) was measured for various regions of each vertebra using a Lunar Piximus DXA scanner. The distribution of the applied compressive force (1.5 kN) between the anterior and posterior halves of the vertebral body was calculated by pulling a needle-mounted pressure transducer along the sagittal midline of the adjacent disc. Pressure measurements were integrated over area to give force. Anterior and posterior disc forces were subtracted from the applied 1.5 kN to indicate loading of the neural arch. Measurements were repeated with the specimens positioned to simulate various postures in life. The strength of each motion segment was determined by compressing it to failure while positioned in a forward stooped posture. Disc and vertebral morphology were assessed from radiographs, and from digital photographs of tissue sections.

Results: Load-bearing by the neural arch in erect posture increased in the presence of intervertebral disc degeneration, and was inversely proportional to the average height of the disc (P< 0.01). High neural arch load-bearing was associated with relatively low BMD in the anterior vertebral body (P< 0.01), and with low compressive strength (P< 0.0001). BMD in the anterior region of the vertebral body was the best univariate predictor of compressive strength (R2 = 0.78). Stepwise multiple linear regression showed that 86% of the variance in compressive strength could be explained by the following: anterior vertebral body BMD, vertebral body X-sectional area, and neural arch load-bearing (% of applied load). Forcing age, gender and spinal level into the model did little to improve the prediction.

Discussion and Conclusions: Results strongly support our hypothesis. Evidently, intervertebral disc degeneration and narrowing cause the neural arch to “stress shield” the anterior vertebral body whenever the spine is held erect. This leads to reduced BMD in the anterior vertebral body, weakening the spine when it is loaded in a stooped posture. The small age-dependence of results can be attributed to the relatively narrow age range of specimens tested. Vertebral fracture risk can best be assessed from BMD measured in the anterior half of the vertebral body.

Correspondence should be addressed to Mr Carlos Wigderowitz, Honorary Secretary BORS, University Dept of Orthopaedic & Trauma Surgery, Ninewells Hospital & Medical School, Dundee DD1 9SY.