Kathryn S. Strand , Elizabeth Silvestro , Iman Naqvi , Michael W. Hast
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Commercially available synthetic clavicles had 57.8–203% higher superior-inferior bending rigidity (p < 0.0001), 80.9–198% higher axial stiffness (p < 0.001), and 314–557% higher torsional rigidity (p < 0.05) on average than AM and cadaveric clavicles. Cadaveric and AM clavicles printed from a BoneMatrix/VeroWhite composite material had similar failure mechanisms under axial compression while AM VeroWhite clavicles experienced catastrophic failure, but these groups did not have significantly different ultimate failure loads. Together, these results demonstrate that current commercially available synthetic clavicles may be too rigid to emulate the mechanical properties of elderly cadaveric clavicles, and that AM bone models can closely mimic these cadaveric bones in a variety of biomechanical loading schemes. These results show promising applications for future work using 3D printed bone surrogates for biomechanical analysis of orthopaedic implants and other surgical repair techniques.</div></div>","PeriodicalId":380,"journal":{"name":"Journal of the Mechanical Behavior of Biomedical Materials","volume":"160 ","pages":"Article 106774"},"PeriodicalIF":3.3000,"publicationDate":"2024-10-12","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Elastic properties of 3D printed clavicles are closer to cadaveric bones of elderly donors than commercial synthetic bones\",\"authors\":\"Kathryn S. Strand , Elizabeth Silvestro , Iman Naqvi , Michael W. 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引用次数: 0
摘要
合成骨模型由于成本低、可变性小,在骨科研究中的作用越来越大,而且已被证明在生物力学方面与人体骨骼具有多种等效性。骨科应用中增材制造(AM)的兴起为构建用于生物力学测试应用的合成全骨模型提供了机会,但目前还缺乏将这些 AM 模型与尸体或市场上可买到的代用骨进行比较的研究。本研究通过无损循环四点弯曲、轴向压缩和扭转,以及最终的轴向压缩测试,比较了 3D 打印锁骨模型与市售(第四代锯骨)和人体尸体锁骨的机械性能。与AM和尸体锁骨相比,市售合成锁骨的上下弯曲刚度平均高出57.8-203%(p <0.0001),轴向刚度平均高出80.9-198%(p <0.001),扭转刚度平均高出314-557%(p <0.05)。由 BoneMatrix/VeroWhite 复合材料打印而成的尸体和 AM 锁骨在轴向压缩下具有相似的失效机制,而 AM VeroWhite 锁骨则经历了灾难性失效,但这两组的最终失效载荷并无显著差异。这些结果共同表明,目前市售的合成锁骨可能过于坚硬,无法模拟老年尸体锁骨的机械性能,而 AM 骨模型可以在各种生物力学加载方案中近似模拟这些尸体骨骼。这些结果表明,未来使用三维打印骨替代物对骨科植入物和其他外科修复技术进行生物力学分析的工作大有可为。
Elastic properties of 3D printed clavicles are closer to cadaveric bones of elderly donors than commercial synthetic bones
Synthetic bone models have increasing utility in orthopaedic research due to their low cost and low variability and have been shown to be biomechanically equivalent to human bones in a variety of ways. The rise in additive manufacturing (AM) for orthopaedic applications presents an opportunity to construct synthetic whole-bone models for biomechanical testing applications, but there is a lack of research comparing these AM models to cadaveric or commercially available bone surrogates. This study compares the mechanical properties of 3D printed clavicle models to commercially available (4th generation Sawbones) and human cadaveric clavicles via nondestructive cyclic 4-point bending, axial compression, and torsion, and a final axial compression test to failure. Commercially available synthetic clavicles had 57.8–203% higher superior-inferior bending rigidity (p < 0.0001), 80.9–198% higher axial stiffness (p < 0.001), and 314–557% higher torsional rigidity (p < 0.05) on average than AM and cadaveric clavicles. Cadaveric and AM clavicles printed from a BoneMatrix/VeroWhite composite material had similar failure mechanisms under axial compression while AM VeroWhite clavicles experienced catastrophic failure, but these groups did not have significantly different ultimate failure loads. Together, these results demonstrate that current commercially available synthetic clavicles may be too rigid to emulate the mechanical properties of elderly cadaveric clavicles, and that AM bone models can closely mimic these cadaveric bones in a variety of biomechanical loading schemes. These results show promising applications for future work using 3D printed bone surrogates for biomechanical analysis of orthopaedic implants and other surgical repair techniques.
期刊介绍:
The Journal of the Mechanical Behavior of Biomedical Materials is concerned with the mechanical deformation, damage and failure under applied forces, of biological material (at the tissue, cellular and molecular levels) and of biomaterials, i.e. those materials which are designed to mimic or replace biological materials.
The primary focus of the journal is the synthesis of materials science, biology, and medical and dental science. Reports of fundamental scientific investigations are welcome, as are articles concerned with the practical application of materials in medical devices. Both experimental and theoretical work is of interest; theoretical papers will normally include comparison of predictions with experimental data, though we recognize that this may not always be appropriate. The journal also publishes technical notes concerned with emerging experimental or theoretical techniques, letters to the editor and, by invitation, review articles and papers describing existing techniques for the benefit of an interdisciplinary readership.