Background: Each part of the rear bone structure can become an anchor point for an attachment device. The objective of this study was to evaluate the stiffness and strength of different parts of the rear lumbar bone structure by axial compression damage experiments. Methods: Five adult male lumbar bone structures from L2 to L5 were exposed. The superior and inferior articular processes, upper and lower edges of the lamina, and upper and lower edges of the spinous process were observed and isolated and then divided into six groups (n=10). The specimens were placed between the compaction disc and the load platform in a universal testing machine, which was first preloaded to 5.0N tension to eliminate water on the surface and then loaded to the specimen curve decline at a constant tension loading rate of 0.01mm/s, until the specimens had been destroyed. Results: Significant differences in mechanical properties were found among different parts of the rear lumbar bone structure. Compared with other parts, the lower edge of the lamina has good mechanical properties, which have a high modulus of elasticity; the superior and inferior articular processes have greater ultimate strength, which can withstand greater compressive loads; and the mechanical properties of the spinous process are poor, and it is significantly stiffer and weaker than the lamina and articular processes. Conclusion: These data can be useful in future spinal biomechanics research leading to better biomechanical compatibility and provide theoretical references for spinal implant materials.
CITATION STYLE
Li, J., Huang, S., Tang, Y., Wang, X., & Pan, T. (2017). Biomechanical analysis of the posterior bony column of the lumbar spine. Journal of Orthopaedic Surgery and Research, 12(1). https://doi.org/10.1186/s13018-017-0631-y
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