使用可变角度锁定型股骨假体周围钢板系统对骨折固定结构进行生物力学评估。
Biomechanical evaluation of fracture fixation constructs using a variable-angle locked periprosthetic femur plate system.
作者信息
Hoffmann Martin F, Burgers Travis A, Mason James J, Williams Bart O, Sietsema Debra L, Jones Clifford B
机构信息
Van Andel Research Institute, Grand Rapids, MI, USA; Grand Rapids Medical Education Partners, Grand Rapids, MI, USA; Orthopaedic Associates of Michigan, Grand Rapids, MI, USA; Department of Surgery, BG-University Hospital Bergmannsheil, Ruhr-University Bochum, Germany.
Van Andel Research Institute, Grand Rapids, MI, USA.
出版信息
Injury. 2014 Jul;45(7):1035-41. doi: 10.1016/j.injury.2014.02.038. Epub 2014 Mar 11.
BACKGROUND
In the United States there are more than 230,000 total hip replacements annually, and periprosthetic femoral fractures occur in 0.1-4.5% of those patients. The majority of these fractures occur at the tip of the stem (Vancouver type B1). The purpose of this study was to compare the biomechanically stability and strength of three fixation constructs and identify the most desirable construct.
METHODS
Fifteen medium adult synthetic femurs were implanted with a hip prosthesis and were osteotomized in an oblique plane at the level of the implant tip to simulate a Vancouver type B1 periprosthetic fracture. Fractures were fixed with a non-contact bridging periprosthetic proximal femur plate (Zimmer Inc., Warsaw, IN). Three proximal fixation methods were used: Group 1, bicortical screws; Group 2, unicortical screws and one cerclage cable; and Group 3, three cerclage cables. Distally, all groups had bicortical screws. Biomechanical testing was performed using an axial-torsional testing machine in three different loading modalities (axial compression, lateral bending, and torsional/sagittal bending), next in axial cyclic loading to 10,000 cycles, again in the three loading modalities, and finally to failure in torsional/sagittal bending.
RESULTS
Group 1 had significantly greater load to failure and was significantly stiffer in torsional/sagittal bending than Groups 2 and 3. After cyclic loading, Group 2 had significantly greater axial stiffness than Groups 1 and 3. There was no difference between the three groups in lateral bending stiffness. The average energy absorbed during cyclic loading was significantly lower in Group 2 than in Groups 1 and 3.
CONCLUSIONS
Bicortical screw placement achieved the highest load to failure and the highest torsional/sagittal bending stiffness. Additional unicortical screws improved axial stiffness when using cable fixation. Lateral bending was not influenced by differences in proximal fixation.
CLINICAL RELEVANCE
To treat periprosthetic fractures, bicortical screw placement should be attempted to maximize load to failure and torsional/sagittal bending stiffness.
背景
在美国,每年进行超过23万例全髋关节置换手术,其中0.1% - 4.5%的患者会发生假体周围股骨骨折。这些骨折大多发生在柄的尖端(温哥华B1型)。本研究的目的是比较三种固定结构的生物力学稳定性和强度,并确定最理想的结构。
方法
将15个中等大小的成人合成股骨植入髋关节假体,并在植入物尖端水平的斜面上进行截骨,以模拟温哥华B1型假体周围骨折。骨折用非接触式桥接假体周围股骨近端钢板(Zimmer公司,印第安纳州华沙)固定。使用了三种近端固定方法:第1组,双皮质螺钉;第2组,单皮质螺钉和一根环扎钢缆;第3组,三根环扎钢缆。在远端,所有组均使用双皮质螺钉。使用轴向 - 扭转试验机在三种不同加载方式(轴向压缩、侧向弯曲和扭转/矢状面弯曲)下进行生物力学测试,接着进行轴向循环加载至10,000次循环,再次在三种加载方式下测试,最后在扭转/矢状面弯曲测试中直至失效。
结果
第1组的失效载荷明显更大,并且在扭转/矢状面弯曲时比第2组和第3组明显更硬。循环加载后,第2组的轴向刚度明显大于第1组和第3组。三组在侧向弯曲刚度方面没有差异。第2组在循环加载期间吸收的平均能量明显低于第1组和第3组。
结论
双皮质螺钉固定实现了最高的失效载荷和最高的扭转/矢状面弯曲刚度。在使用钢缆固定时,额外的单皮质螺钉提高了轴向刚度。侧向弯曲不受近端固定差异的影响。
临床意义
为治疗假体周围骨折,应尝试采用双皮质螺钉固定以最大化失效载荷和扭转/矢状面弯曲刚度。
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