Surgical simulation of curved periacetabular osteotomy in four types of developmental dysplasia of the hip using finite element analysis and identification of the optimal rotation angle of the osteotomized bone.

IF 1.5 4区 医学 Q3 ORTHOPEDICS
Takahiro Igei, Satoshi Nakasone, Masato Ishihara, Masamichi Onaga, Fumiyuki Washizaki, Sakura Kuniyoshi, Kotaro Nishida
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引用次数: 0

Abstract

Background: Patients with developmental dysplasia of the hip (DDH) undergo curved periacetabular osteotomy (CPO) to prevent progressive osteoarthritis. The acetabulum's morphology varies with in each DDH type. Therefore, developing a three-dimensional preoperative plan is important in CPO. However, the optimal rotation angle of the osteotomized bone remains unclear. This study aimed to examine the contact pressure (CP) of the acetabular cartilage in each DDH type using the finite element analysis and the optimal rotation angle of the osteotomized bone in surgical simulation.

Methods: This study included 23 patients (24 hips) with DDH who underwent CPO. The DDH type was determined based on a previously reported DDH type classification using radar charts. Four patients, with each patient presenting with one deficiency type, were selected for analysis. The preoperative computed tomography scan data of each patient were analyzed using a finite element analysis software. Based on each DDH type, the following CPO models were established: the preoperative model, the model rotated 10°, 20°, 30°, and 40° laterally, each lateral rotation model with 10° anterior rotation, and each lateral rotation model with 10° external rotation. Furthermore, the acetabular cartilage and the femoral head cartilage were created. The mesh model based on a 4-mm tetrahedron was generated from the CPO model. The load was set in the one-leg standing position (femur: 500 N, grater trochanter: 1000 N). The medial pubic bone, distal femur, and superior rim of the ilium were constrained. The CP of the acetabular cartilage and the number of contact surfaces in each model were evaluated. The rotation angle that was most effective in reducing the CP was examined.

Results: According to the mean CP, the optimal rotation angles of the osteotomized bone in mild, anterior, posterior, and global type deficiencies were 20° laterally, 30° laterally, 30° laterally with 10° anterior rotation, and 30° laterally with 10° anterior rotation, respectively. Based on the contour diagram, the CPO models rotated anteriorly or externally increased the contact surface. The CP of the models rotated 40° laterally did not improve to greater extent than that of the models rotated 30° laterally.

Conclusions: The optimal rotation angle of the osteotomized bone should be determined based on the DDH type.

利用有限元分析和确定截骨骨的最佳旋转角度,对四种髋关节发育不良类型的弧形髋臼周围截骨术进行手术模拟。
背景:髋关节发育不良(DDH)患者需要接受髋臼周围弯曲截骨术(CPO),以预防渐进性骨关节炎。每种 DDH 类型的髋臼形态各异。因此,制定三维术前计划对 CPO 非常重要。然而,截骨骨的最佳旋转角度仍不明确。本研究旨在利用有限元分析法研究每种 DDH 类型中髋臼软骨的接触压力(CP)以及手术模拟中截骨骨的最佳旋转角度:这项研究包括23名接受CPO手术的DDH患者(24个髋关节)。DDH类型是根据之前报道的雷达图DDH类型分类确定的。研究选择了四名患者进行分析,每名患者有一种缺损类型。使用有限元分析软件对每位患者的术前计算机断层扫描数据进行了分析。根据每种 DDH 类型,建立了以下 CPO 模型:术前模型,侧向旋转 10°、20°、30° 和 40°的模型,每个侧向旋转模型前旋 10°,每个侧向旋转模型外旋 10°。此外,还创建了髋臼软骨和股骨头软骨。根据 CPO 模型生成了基于 4 毫米四面体的网格模型。负载设定为单腿站立姿势(股骨:500 N,大转子:1000 N)。耻骨内侧、股骨远端和髂骨上缘受到约束。对每个模型的髋臼软骨CP和接触面数量进行了评估。研究结果显示,旋转角度对减少 CP 最有效:根据平均 CP 值,轻度、前方、后方和整体型缺损的截骨最佳旋转角度分别为外侧 20°、外侧 30°、外侧 30°、前旋 10°和外侧 30°、前旋 10°。根据轮廓图,CPO 模型的前旋或外旋增加了接触面。横向旋转 40° 模型的 CP 改善程度并不比横向旋转 30° 模型的 CP 改善程度大:结论:应根据 DDH 类型确定截骨的最佳旋转角度。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of Orthopaedic Science
Journal of Orthopaedic Science 医学-整形外科
CiteScore
3.00
自引率
0.00%
发文量
290
审稿时长
90 days
期刊介绍: The Journal of Orthopaedic Science is the official peer-reviewed journal of the Japanese Orthopaedic Association. The journal publishes the latest researches and topical debates in all fields of clinical and experimental orthopaedics, including musculoskeletal medicine, sports medicine, locomotive syndrome, trauma, paediatrics, oncology and biomaterials, as well as basic researches.
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