Effect of Plate Screw Configuration on Construct Stiffness and Plate Strain in a Synthetic Short Fragment Small Gap Fracture Model Stabilized with a 12-Hole 3.5-mm Locking Compression Plate.

IF 1 2区农林科学 Q3 VETERINARY SCIENCES

Veterinary and Comparative Orthopaedics and Traumatology Pub Date : 2025-05-01 Epub Date: 2024-10-04 DOI:10.1055/s-0044-1791701

Fabian N Trefny, Mark R Glyde, Giselle L Hosgood, Robert E Day, Alex Hayes

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引用次数: 0

Abstract

Objective: The aim of the study was to determine the effect of a short and long working length screw configuration on construct stiffness and plate strain in a synthetic, short fragment, small gap fracture model stabilized with a 12-hole 3.5-mm locking compression plate (LCP).

Study design: Six replicates of short and long working length constructs on a short fragment, small gap fracture model underwent four-point bending. Construct stiffness and plate strain were compared across working length and along the plate.

Results: With the LCP on the compression surface (compression bending), the short working length had a significantly higher construct stiffness and lower plate strain than the long working length. Conversely, with the LCP on the tension surface (tension bending), transcortical contact between 150 and 155 N induced load sharing at the fracture gap, which significantly increased construct stiffness and decreased plate strain in the long working length. At 100 N (precontact), the short working length had a significantly higher construct stiffness and lower plate strain than the long working length, comparable with our compressing bending results.

Conclusion: In compression bending, and before transcortical contact occurred in tension bending, the short working length had a significantly higher construct stiffness and lower plate strain than the long working length. Load sharing due to transcortical contact observed in our model in tension bending will vary with fracture gap, working length, and loading condition. These results must be interpreted with caution when considering clinical relevance or potential in vivo biomechanical advantages.

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在使用 12 孔 3.5 毫米锁定加压钢板稳定的合成短片小间隙骨折模型中，钢板螺钉配置对结构刚度和钢板应变的影响。

研究目的研究旨在确定长短工作长度螺钉配置对使用 12 孔 3.5 毫米锁定加压钢板（LCP）稳定的合成短片段小间隙骨折模型的结构刚度和钢板应变的影响：研究设计：对短片段、小间隙骨折模型上的短工作长度和长工作长度结构进行六次重复的四点弯曲试验。对不同工作长度和沿钢板的结构刚度和钢板应变进行了比较：结果：当 LCP 位于压缩面上时（压缩弯曲），短工作长度的构造刚度明显高于长工作长度的构造刚度，而钢板应变则低于长工作长度的构造刚度。相反，当 LCP 位于拉伸面上时（拉伸弯曲），150 至 155 N 的跨皮层接触会导致断裂间隙分担荷载，从而显著提高构造刚度，降低长工作长度板的应变。在 100 N 时（接触前），短工作长度的构造刚度明显高于长工作长度，板应变也低于长工作长度，这与我们的压缩弯曲结果相当：结论：在压缩弯曲和拉伸弯曲中发生皮层接触之前，短工作长度的结构刚度明显高于长工作长度，板应变也低于长工作长度。我们的模型在拉伸弯曲中观察到的皮层接触导致的荷载分担会随着断裂间隙、工作长度和加载条件的不同而变化。在考虑临床相关性或潜在的体内生物力学优势时，必须谨慎解释这些结果。

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

Veterinary and Comparative Orthopaedics and Traumatology 农林科学-动物学

CiteScore

2.00

自引率

15.40%

发文量

审稿时长

18-36 weeks

期刊介绍： Veterinary and Comparative Orthopaedics and Traumatology (VCOT) is the most important single source for clinically relevant information in orthopaedics and neurosurgery available anywhere in the world today. It is unique in that it is truly comparative and there is an unrivalled mix of review articles and basic science amid the information that is immediately clinically relevant in veterinary surgery today.