Does Sagittal Alignment Matter? A Biomechanical Look at Pinning Pediatric Supracondylar Humerus Fractures.

IF 1.4 3区医学 Q3 ORTHOPEDICS

Journal of Pediatric Orthopaedics Pub Date : 2024-09-10 DOI:10.1097/bpo.0000000000002809

Ryan Serbin,Marc Duemmler,Kirby Bonvillain,Kelsie Coe,Nahir A Habet,Susan Odum,Michael Paloski

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Abstract

OBJECTIVE Closed manipulation and percutaneous pinning is standard of care for displaced supracondylar humerus fractures, yet the optimal pin configuration, particularly in the sagittal plane, is not well defined. This study evaluates how sagittal plane pin variations affect construct strength biomechanically. METHODS One hundred synthetic pediatric humerus models were used to emulate supracondylar humerus fracture. The models were pinned using 4 different configurations uniformly divergent in the coronal plane with variations in the sagittal plane: (1) 2 diverging pins with the lateral pin anterior (n = 25), (2) 2 diverging pins with the lateral pin posterior (n = 25), (3) 2 parallel pins (n = 25), and (4) 3 parallel pins (n = 25). The models were tested under bending (flexion, extension, and varus) and rotational (internal and external) forces, measuring stiffness and torque. Statistical analyses identified significant differences across configurations. RESULTS The 2-pin parallel configuration (9.68 N/mm in extension, 8.76 N/mm in flexion, 0.14 N-m/deg in internal rotation, and 0.14 N-m/deg in external rotation) performed similarly to the 3-pin parallel setup (10.77 N/mm in extension, 7.78 N/mm in flexion, 0.16 N-m/deg in internal rotation, and 0.14 N-m/deg in external rotation), with no significant differences in stiffness. In contrast, both parallel configurations significantly outperformed the 2-pin anterior (5.22 N/mm in extension, 5.7 N/mm in flexion, 0.11 N-m/deg in internal rotation and 0.10 N-m/deg in external rotation) and posterior (9.86 N/mm in extension, 8.31 N/mm in flexion, 0.12N-m/deg in internal rotation, and 0.11 N-m/deg in external rotation) configurations in resisting deformation. No notable disparities were observed in varus loading among any configurations. CONCLUSIONS This study illuminates the sagittal plane's role in construct stability. It suggests that, when utilizing 2-pins, parallel configurations in the sagittal plane improve biomechanical stability. In addition, it suggests avoiding the lateral anterior pin configuration due to its biomechanical inferiority. Further research should assess ultimate strength and compare various 3-pin configurations to better delineate differences between 2-pin and 3-pin configurations regarding sagittal plane alignment. LEVEL OF EVIDENCE Level III-biomechanical study.

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矢状对齐重要吗？从生物力学角度看小儿肱骨髁上骨折的钢钉固定。

目的闭合操作和经皮置入钢钉是治疗移位肱骨髁上骨折的标准方法，但最佳的钢钉配置，尤其是矢状面上的钢钉配置，尚未得到很好的定义。本研究评估了矢状面针的变化对生物力学结构强度的影响。方法用 100 个合成小儿肱骨模型模拟肱骨髁上骨折。这些模型采用四种不同的结构进行固定，这些结构在冠状面上均匀发散，而在矢状面上有所变化：(1) 2个发散针，侧针在前方（n = 25）；(2) 2个发散针，侧针在后方（n = 25）；(3) 2个平行针（n = 25）；(4) 3个平行针（n = 25）。这些模型在弯曲（屈曲、伸展和外翻）和旋转（内部和外部）力作用下进行了测试，测量了硬度和扭矩。结果2针平行配置（伸展时9.68 N/mm，屈曲时8.76 N/mm，内旋时0.14 N-m/deg，外旋时0.14 N-m/deg）与3针平行配置（伸展时10.77 N/mm，屈曲时7.78 N/mm，内旋时0.16 N-m/deg，外旋时0.14 N-m/deg）性能相似，刚度无显著差异。相比之下，两种平行结构在抵抗变形方面明显优于双针前结构（伸展5.22 N/mm，屈曲5.7 N/mm，内旋0.11 N-m/deg，外旋0.10 N-m/deg）和后结构（伸展9.86 N/mm，屈曲8.31 N/mm，内旋0.12 N-m/deg，外旋0.11 N-m/deg）。本研究阐明了矢状面在结构稳定性中的作用。该研究表明，在使用 2 针时，矢状面上的平行配置可提高生物力学稳定性。此外，它还建议避免使用外侧前方针脚配置，因为这种配置在生物力学上效果较差。进一步的研究应评估终极强度并比较各种 3 针配置，以更好地界定 2 针和 3 针配置在矢状面对齐方面的差异。

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 Pediatric Orthopaedics 医学-小儿科

CiteScore

3.30

自引率

17.60%

发文量

512

审稿时长

6 months

期刊介绍： Journal of Pediatric Orthopaedics is a leading journal that focuses specifically on traumatic injuries to give you hands-on on coverage of a fast-growing field. You''ll get articles that cover everything from the nature of injury to the effects of new drug therapies; everything from recommendations for more effective surgical approaches to the latest laboratory findings.