The Effect of Locking Head Inserts on the Biomechanical Properties of a 3.5-mm Broad Locking Compression Plate When Used in an Open Fracture-Gap Model.

IF 1 2区农林科学 Q3 VETERINARY SCIENCES Veterinary and Comparative Orthopaedics and Traumatology Pub Date : 2025-01-21 DOI:10.1055/s-0044-1800973

William T G Hawker, Noel Moens, Bruce Guest, Michelle Oblak, Melissa MacIver, John Runciman

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Abstract

Objective: To determine the effect of locking head inserts (LHI) on plate strain, stiffness, and deformation when applied to a 3.5-mm broad locking compression plate (LCP) in an open fracture-gap model.

Study design: Six, 13-hole, 3.5-mm broad LCP were secured to epoxy bone models with a 10 mm central defect and 1 mm plate offset. Two peripheral locking screws were placed in each segment, with the remaining screw holes left unfilled. Three strain gauges were glued to each LCP at anticipated regions of maximum strain. Constructs underwent cyclic uniaxial loading at a rate of 20 mm/min to 400 N in three different configurations (Configuration 1: no LHI, Configuration 2: 3 LHI, Configuration 3: 9 LHI). LHI were tightened to 4 Nm of torque. A data acquisition system was used to collect implant strain during testing. Construct stiffness and deformation were recorded by the biomechanical testing machine.

Results: Maximum implant strain was recorded at the central screw hole directly over the simulated fracture gap in all configurations (Mdn 1,837.3 µε [interquartile range: 1,805.1-1,862.0]). There was no difference in implant peak-to-peak strain with addition of LHI at all three gauges (Gauge 1 [p = 0.847], Gauge 2 [p = 0.847], Gauge 3 [p = 0.311]). Similarly, peak-to-peak displacement (p = 0.069) and axial construct stiffness (p = 0.311) did not change with the addition of LHI.

Conclusion: The addition of LHI to a 3.5-mm broad LCP construct was not shown to have an effect on plate strain, stiffness, or deformation.

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锁定头植入物对3.5 mm宽锁定加压钢板用于开放性骨折间隙模型生物力学性能的影响

目的：探讨3.5 mm宽锁定加压钢板（LCP）应用于开放性骨折间隙模型时，锁定头插入物（LHI）对钢板应变、刚度和变形的影响。研究设计：6个，13孔，3.5 mm宽LCP固定在环氧骨模型上，中心缺损10mm，钢板偏移1mm。每个节段放置两枚外围锁定螺钉，其余螺钉孔不填充。三个应变片粘在每个LCP的最大应变预期区域。构建体在三种不同配置（配置1：无LHI，配置2:3 LHI，配置3:9 LHI）下以20 mm/min的速度循环单轴加载至400 N。LHI被拧紧到4 Nm的扭矩。数据采集系统用于在测试过程中收集种植体应变。生物力学试验机记录结构刚度和变形。结果：在所有构型下，在模拟骨折间隙正上方的中心螺钉孔处均记录到了最大种植体应变（Mdn为1,837.3µε[四分位数范围：1,805.1-1,862.0]）。添加LHI后，三种规格（规格1 [p = 0.847]，规格2 [p = 0.847]，规格3 [p = 0.311]）的种植体峰间应变均无差异。同样，峰间位移（p = 0.069）和轴向结构刚度（p = 0.311）没有随着LHI的加入而改变。结论：在3.5 mm宽的LCP结构中添加LHI对钢板应变、刚度或变形没有影响。

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.