Residual Stresses in Surgical Growing Rods.

IF 1.7 4区 医学 Q4 BIOPHYSICS Journal of Biomechanical Engineering-Transactions of the Asme Pub Date : 2024-01-01 DOI:10.1115/1.4063745
Maïté Croonenborghs, Karim Ismail, Maryline Mousny, Laurent Delannay, Joris Everaerts, Alexander M Korsunsky, Pascal J Jacques, Thomas Pardoen
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Abstract

The treatment of early onset scoliosis using surgical growing rods suffers from high failure rate. Fatigue resistance can be improved by inducing compressive residual stresses within the near surface region. An in-depth investigation of the residual stresses profile evolution is performed through the sequence of material processing steps followed by surgeons handling operations, in connection to material properties. The final goal is to guide further improvements of growing rod lifetime. Residual stress evaluation was carried out on Ti-6Al-4V rods using digital image correlation applied to microbeam ring-core milling by focused ion beam. This provided experimental stress profiles in shot-peened rods before and after bending and demonstrated that compressive residual stresses are maintained at both concave and convex rod sides. A finite element model using different core and skin conditions was validated by comparison to experiments. The combination of an initial shot peening profile associated with a significant level of backstress was found to primarily control the generation of compressive stresses at the rod surface after bending. Guidelines to promote larger compressive stresses at the surface were formulated based on a parametric analysis. The analysis revealed the first order impact of the initial yield strength, kinematic hardening parameters and intensity of the shot peening operation, while the bending angle and the depth of shot peening stresses were found to be of minor importance. Materials exhibiting large kinematic hardening and low yield strength should be selected in order to induce compressive residual stresses at key fatigue initiation site.

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手术生长棒中的残余应力。
使用手术生长棒治疗早发性脊柱侧凸的失败率很高。可以通过在近表面区域内产生压缩残余应力来提高抗疲劳性。通过一系列材料加工步骤,然后由外科医生处理与材料特性相关的操作,对残余应力分布演变进行深入研究。最终目标是指导进一步提高生长棒的使用寿命。将数字图像相关技术应用于聚焦离子束微束环芯铣削,对Ti6Al4V棒的残余应力进行了评估。这提供了喷丸处理棒在弯曲前后的实验应力分布,并证明了在凹形和凸形棒侧都保持了压缩残余应力。通过与实验的比较,验证了使用不同堆芯和表皮条件的有限元模型。发现与显著水平的背应力相关的初始喷丸轮廓的组合主要控制弯曲后杆表面压缩应力的产生。在参数分析的基础上制定了促进表面更大压缩应力的指南。分析表明,初始屈服强度、运动硬化参数和喷丸操作强度的一阶影响较小,而弯曲角和喷丸应力深度的影响较小。应选择表现出大的运动硬化和低屈服强度的材料,以便在关键的疲劳起始位置产生压缩残余应力。
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来源期刊
CiteScore
3.40
自引率
5.90%
发文量
169
审稿时长
4-8 weeks
期刊介绍: Artificial Organs and Prostheses; Bioinstrumentation and Measurements; Bioheat Transfer; Biomaterials; Biomechanics; Bioprocess Engineering; Cellular Mechanics; Design and Control of Biological Systems; Physiological Systems.
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