The Effect of Working Length, Fracture, and Screw Configuration on Plate Strain in a 3.5-mm LCP Bone Model of Comminuted Fractures

VCOT open Pub Date : 2023-07-01 DOI:10.1055/s-0043-1774371

S.H. Wainberg, N.M.M. Moens, Z. Ouyang, J. Runciman

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Abstract

Abstract Introduction This study provides a comprehensive examination of plate strain under realistic fracture configurations. The effect of plate working length, plate contact, fracture length, and position on strain was evaluated using bone surrogates subjected to “load-controlled,” nondestructive conditions. Materials and Methods Five 3.5-mm locking compression plates (LCP) were instrumented with six strain gauges. The gauges were glued between holes in predetermined locations marked by laser engraving. Nine fracture models were created using bone surrogate, each representing a combination of the criteria under study: long versus short working length, degree of plate compression, fracture location, and fracture length. All five plates were tested under each of the nine configurations. The constructs were mounted in an Instron testing machine with a 5-kN load cell. Each specimen was cyclically loaded at a rate of 5 mm/min to 50, 100, and 200 N. Results Decreased plate strain was noted with a short plate working length in all fracture configurations (p < 0.05). Increasing the plate working length increased the strain at higher loads and on the plate adjacent to the fracture gap. The size of the fracture gap and fracture location had minimal effects on plate strain (p < 0.05). Elevation of the plate off the bone (1.5 mm) resulted in increased plate strain under all loading conditions (p < 0.05). Conclusion Our null hypothesis was rejected in that a short plate working length resulted in decreased plate strain in all comminuted fracture configurations. Our secondary hypothesis was validated in that elevation of the plate from the bone resulted in increased strain in all configurations. As plate strain identifies regions of mechanical weakness whereby a construct may prematurely fail by acute overload or cyclic fatigue, identifying factors that may increase plate strain allows the surgeon to reduce these variables as much as possible to reduce the incidence of implant failure and subsequent fracture failure.

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3.5 mm LCP粉碎性骨折模型中工作长度、骨折点和螺钉配置对钢板应变的影响

摘要:本研究对实际断裂形态下的板应变进行了全面的研究。在“负载控制”的非破坏性条件下，使用骨替代物评估钢板工作长度、钢板接触、骨折长度和位置对应变的影响。材料与方法对5块3.5 mm锁定压缩板(LCP)进行6个应变片的测量。这些量规被粘在激光雕刻的预定位置的孔之间。使用骨替代物创建了9个骨折模型，每个模型都代表了所研究标准的组合:长与短工作长度、钢板受压程度、骨折位置和骨折长度。所有五个板都在九种配置下进行了测试。这些结构被安装在带有5kn称重传感器的Instron测试机上。每个试样以5毫米/分钟的速率循环加载至50、100和200牛顿。结果在所有断裂构型中，随着板工作长度的缩短，板应变减小(p <0.05)。增加板的工作长度增加了在高载荷和靠近断裂间隙的板上的应变。断裂间隙的大小和断裂位置对板应变的影响最小(p <0.05)。在所有载荷条件下，钢板离骨抬高(1.5 mm)导致钢板应变增加(p <0.05)。结论我们的零假设被否定了，短的钢板工作长度导致所有粉碎性骨折形态的钢板应变降低。我们的第二个假设得到了验证，即钢板从骨头上抬高导致所有构型的应变增加。由于钢板应变识别出机械薄弱的区域，在此区域内假体可能因急性超载或循环疲劳而过早失效，识别可能增加钢板应变的因素使外科医生能够尽可能地减少这些变量，以减少植入物失败和随后的骨折失败的发生率。

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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