新型低刚度脊柱后路植入物在退变脊柱模型上前侧剪切载荷作用下的行为特征

Characterization of the behavior of a novel low-stiffness posterior spinal implant under anterior shear loading on a degenerative spinal model.

作者信息

Melnyk Angela D, Chak Jason D, Singh Vaneet, Kelly Adrienne, Cripton Peter A, Fisher Charles G, Dvorak Marcel F, Oxland Thomas R

机构信息

Department of Mechanical Engineering, University of British Columbia, 818 West 10th Ave., Vancouver, BC, V5Z 1M9, Canada.

出版信息

Eur Spine J. 2015 Apr;24(4):775-82. doi: 10.1007/s00586-014-3735-7. Epub 2015 Jan 6.

DOI:10.1007/s00586-014-3735-7

PMID:25559294

Abstract

PURPOSE

Dynamic implants have been developed to address potential adjacent level effects due to rigid instrumentation. Rates of revision surgeries may be reduced by using improved implants in the primary surgery. Prior to clinical use, implants should be rigorously tested ex vivo. The objective of our study was to characterize the load-sharing and kinematic behavior of a novel low-stiffness spinal implant.

METHODS

A human cadaveric model of degenerative spondylolisthesis was tested in shear. Lumbar functional spinal units (N = 15) were tested under a static 300 N axial compression force and a cyclic anterior shear force (5-250 N). Translation was tracked with a motion capture system. A novel implant was compared to three standard implants with shear stiffness ranging from low to high. All implants were instrumented with strain gauges to measure the supported shear force. Each implant was affixed to each specimen, and the specimens were tested intact and in two progressively destabilized states.

RESULTS

Specimen condition and implant type affected implant load-sharing and specimen translation (p < 0.0001). Implant load-sharing increased across all degeneration-simulating specimen conditions and decreased across the three standard implants (high- to low-stiffness). Translation increased with the three standard implants (trend). The novel implant behaved similarly to the medium-stiffness implant (p > 0.2).

CONCLUSIONS

The novel implant behaved similarly to the medium-stiffness implant in both load-sharing and translation despite having a different design and stiffness. Complex implant design and specimen-implant interaction necessitate pre-clinical testing of novel implants. Further in vitro testing in axial rotation and flexion-extension is recommended as they are highly relevant loading directions for non-rigid implants.

摘要

目的

动态植入物已被研发出来，以解决因刚性器械固定导致的潜在相邻节段效应。在初次手术中使用改良的植入物可能会降低翻修手术的发生率。在临床使用之前，植入物应在体外进行严格测试。我们研究的目的是表征一种新型低刚度脊柱植入物的载荷分担和运动学行为。

方法

对一个退行性椎体滑脱的人体尸体模型进行剪切测试。腰椎功能脊柱单元（N = 15）在300 N的静态轴向压缩力和5 - 250 N的周期性前向剪切力作用下进行测试。使用运动捕捉系统跟踪平移情况。将一种新型植入物与三种剪切刚度从低到高的标准植入物进行比较。所有植入物都安装了应变片以测量所承受的剪切力。将每个植入物固定到每个标本上，标本在完整状态以及两种逐渐失稳的状态下进行测试。

结果

标本状态和植入物类型影响植入物的载荷分担和标本平移（p < 0.0001）。在所有模拟退变的标本状态下，植入物的载荷分担均增加，而在三种标准植入物（从高刚度到低刚度）中则降低。三种标准植入物的平移呈增加趋势。新型植入物的表现与中等刚度植入物相似（p > 0.2）。

结论

尽管新型植入物的设计和刚度不同，但其在载荷分担和平移方面的表现与中等刚度植入物相似。复杂的植入物设计和标本 - 植入物相互作用使得新型植入物有必要进行临床前测试。建议进一步进行轴向旋转和屈伸的体外测试，因为它们是非刚性植入物高度相关的加载方向。

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新型低刚度脊柱后路植入物在退变脊柱模型上前侧剪切载荷作用下的行为特征

Characterization of the behavior of a novel low-stiffness posterior spinal implant under anterior shear loading on a degenerative spinal model.

作者信息

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSIONS

目的

方法

结果

结论

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