Abstract
Vertebroplasty has been widely used for the treatment of osteoporotic compression fractures but the efficacy of the technique has been questioned by the outcomes of randomized clinical trials. Finite‐element (FE) models allow an investigation into the structural and geometric variation that affect the response to augmentation. However, current specimen‐specific FE models are limited due to their poor reproduction of cement augmentation behavior. The aims of this study were to develop new methods of modeling the vertebral body in both a nonaugmented and augmented state. Experimental tests were conducted using human lumbar spine vertebral specimens. These tests included micro‐computed tomography imaging, mechanical testing, augmentation with cement, reimaging, and retesting. Specimen‐specific FE models of the vertebrae were made comparing different approaches to capturing the bone material properties and to modeling the cement augmentation region. These methods significantly improved the modeling accuracy of nonaugmented vertebrae. Methods that used the registration of multiple images (pre‐ and post‐augmentation) of a vertebra achieved good agreement between augmented models and their experimental counterparts in terms of predictions of stiffness. Such models allow for further investigation into how vertebral variation influences the mechanical outcomes of vertebroplasty.
Highlights
Vertebral compression fractures are among the most common types of fractures that patients with osteoporosis experience.[1]
Vertebrae with concentrated volumes of cement had a correlation between density of the vertebrae and the quantity of cement injected before cement leakage occurred
The modeling methods presented in this study were found to provide accurate estimates of the stiffness of nonaugmented human lumbar vertebrae
Summary
Vertebral compression fractures are among the most common types of fractures that patients with osteoporosis experience.[1] Vertebroplasty is widely used as a treatment for such fractures, offering vertebral stability and pain relief. The procedure involves the injection of bone cement into the fractured vertebral body, reducing motion and stabilizing the segment. Finite-element (FE) models are a clear choice to investigate how different types of variation in the procedure, geometry and material properties change the effectiveness of vertebroplasty from a mechanical perspective. While a number of studies have attempted to model cement augmentation in human vertebrae,[5,6,7,8,9,10] few have attempted to JOR Spine.
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