多节段腰椎结构中的节段性椎弓根螺钉固定或横向连接。生物力学分析。

Segmental pedicle screw fixation or cross-links in multilevel lumbar constructs. a biomechanical analysis.

作者信息

Brodke D S, Bachus K N, Mohr R A, Nguyen B K

机构信息

Department of Orthopaedics, Orthopaedic Bioengineering Research Laboratory, University of Utah School of Medicine, Salt Lake City, UT 84112, USA.

出版信息

Spine J. 2001 Sep-Oct;1(5):373-9. doi: 10.1016/s1529-9430(01)00116-4.

DOI:10.1016/s1529-9430(01)00116-4

PMID:14588318

Abstract

BACKGROUND CONTEXT

The placement of segmental pedicle screws and cross-links in short segment posterior pedicle screw constructs has been shown to increase the construct stiffness in some planes. To date, no studies have looked at the contributions of segmental pedicle screw and cross-link placement in longer constructs.

PURPOSE

To evaluate the influence of segmental pedicle screw and/or cross-link placement on flexion/extension, lateral bending and axial torsion stiffness in two- and three-level posterior pedicle screw fixation constructs.

STUDY DESIGN/SETTING: An in vitro biomechanical analysis of two- and three-level posterior pedicle screw constructs with and without segmental fixation and/or cross-links was performed using calf lumbar spines. Stiffness of the constructs was compared.

METHODS

Six calf lumbar specimens were used to test stiffness in one-, two- and three-level posterior pedicle screw fixation constructs in 12 configurations. A custom-made, four-axis spine simulator applied pure cyclical (+/-5 Nm) flexion/extension, lateral bending and axial torsion moments at 0.1 Hz under a constant 50-N axial compressive load. The stiffness of each construct was calculated about each axis of rotation. Data were analyzed using nonparametric techniques with statistical significance determined at alpha less than .05.

RESULTS

The stiffness of the instrumented spines were significantly greater than the noninstrumented intact spines in all loading conditions for one-, two- and three-level constructs. There were no significant changes in flexion/extension stiffness with the addition of either the cross-links or the segmental pedicle screws. In lateral bending, the addition of segmental pedicle screws significantly increased the stiffness in the two- and three-level constructs. The addition of two cross-links increased lateral bending stiffness in the longer three-level constructs, with little change in the two-level constructs. In axial torsion, the progressive addition of cross-links showed a tendency toward increased stiffness in both the two- and three-level constructs. Segmental pedicle screws further increased torsional stiffness of the longer, three-level constructs.

CONCLUSIONS

As the use of segmental spinal instrumentation progresses from one to two and three levels, the contribution of cross-links and segmental pedicle screws to the overall construct stiffness increases.

摘要

背景

在短节段后路椎弓根螺钉结构中置入节段性椎弓根螺钉和横向连接棒已被证明可在某些平面增加结构刚度。迄今为止，尚无研究探讨节段性椎弓根螺钉和横向连接棒在较长结构中的作用。

目的

评估节段性椎弓根螺钉和/或横向连接棒的置入对两级和三级后路椎弓根螺钉固定结构的屈伸、侧弯和轴向扭转刚度的影响。

研究设计/场所：使用小牛腰椎对有无节段固定和/或横向连接棒的两级和三级后路椎弓根螺钉结构进行体外生物力学分析。比较各结构的刚度。

方法

六个小牛腰椎标本用于测试12种配置下一级、两级和三级后路椎弓根螺钉固定结构的刚度。定制的四轴脊柱模拟器在50 N的恒定轴向压缩载荷下，以0.1 Hz的频率施加纯周期性（±5 Nm）的屈伸、侧弯和轴向扭转力矩。计算每个结构绕每个旋转轴的刚度。使用非参数技术分析数据，显著性水平设定为α小于0.05。

结果

在所有加载条件下，一级、两级和三级结构的内固定脊柱刚度均显著大于未内固定的完整脊柱。添加横向连接棒或节段性椎弓根螺钉后，屈伸刚度无显著变化。在侧弯方面，添加节段性椎弓根螺钉显著增加了两级和三级结构的刚度。添加两个横向连接棒增加了较长的三级结构的侧弯刚度，而两级结构变化不大。在轴向扭转方面，逐步添加横向连接棒显示两级和三级结构均有刚度增加的趋势。节段性椎弓根螺钉进一步增加了较长的三级结构的扭转刚度。

结论

随着节段性脊柱内固定从一级发展到两级和三级，横向连接棒和节段性椎弓根螺钉对整体结构刚度的贡献增加。

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多节段腰椎结构中的节段性椎弓根螺钉固定或横向连接。生物力学分析。

Segmental pedicle screw fixation or cross-links in multilevel lumbar constructs. a biomechanical analysis.

作者信息

机构信息

出版信息

BACKGROUND CONTEXT

PURPOSE

METHODS

RESULTS

CONCLUSIONS

背景

目的

方法

结果

结论

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