具有新型交联结构的椎弓根螺钉-棒系统的生物力学分析
Biomechanical Analysis of a Pedicle Screw-Rod System with a Novel Cross-Link Configuration.
作者信息
Nakajima Yasuhiro, Hara Masahito, Umebayashi Daisuke, Haimoto Shoichi, Yamamoto Yu, Nishimura Yusuke, Wakabayashi Toshihiko
机构信息
Department of Neurosurgery, Inazawa Municipal Hospital, Inazawa, Japan.
Department of Neurosurgery, Nagoya University Graduate School of Medicine, Nagoya, Japan.
出版信息
Asian Spine J. 2016 Dec;10(6):993-999. doi: 10.4184/asj.2016.10.6.993. Epub 2016 Dec 8.
STUDY DESIGN
The strength effects of a pedicle screw-rod system supplemented with a novel cross-link configuration were biomechanically evaluated in porcine spines.
PURPOSE
To assess the biomechanical differences between a conventional cross-link pedicle screw-rod system versus a novel cross-link instrumentation, and to determine the effect of the cross-links.
OVERVIEW OF LITERATURE
Transverse cross-link systems affect torsional rigidity, but are thought to have little impact on the sagittal motion of spinal constructs. We tested the strength effects in pullout and flexion-compression tests of novel cross-link pedicle screw constructs using porcine thoracic and lumbar vertebrae.
METHODS
Five matched thoracic and lumbar vertebral segments from 15 porcine spines were instrumented with 5.0-mm pedicle screws, which were then connected with 6.0-mm rods after partial corpectomy in the middle vertebral body. The forces required for construct failure in pullout and flexion-compression tests were examined in a randomized manner for three different cross-link configurations: un-cross-link control, conventional cross-link, and cross-link passing through the base of the spinous process. Statistical comparisons of strength data were analyzed using Student's -tests.
RESULTS
The spinous process group required a significantly greater pullout force for construct failure than the control group (=0.036). No difference was found between the control and cross-link groups, or the cross-link and spinous process groups in pullout testing. In flexion-compression testing, the spinous processes group required significantly greater forces for construct failure than the control and cross-link groups (<0.001 and =0.003, respectively). However, there was no difference between the control and cross-link groups.
CONCLUSIONS
A novel cross-link configuration that features cross-link devices passing through the base of the spinous processes increased the mechanical resistance in pullout and flexion-compression testing compared to un-cross-link constructs. This configuration provided more resistance to middle-column damage under flexion-compression testing than conventional cross-link configuration.
研究设计
在猪脊柱上对补充了新型交联结构的椎弓根螺钉-棒系统的强度效应进行生物力学评估。
目的
评估传统交联椎弓根螺钉-棒系统与新型交联器械之间的生物力学差异,并确定交联的效果。
文献综述
横向交联系统会影响扭转刚度,但被认为对脊柱结构的矢状面运动影响较小。我们使用猪的胸椎和腰椎测试了新型交联椎弓根螺钉结构在拔出和屈伸压缩试验中的强度效应。
方法
从15头猪的脊柱中选取5对匹配的胸腰椎节段,植入5.0毫米的椎弓根螺钉,然后在椎体中部进行部分椎体切除术后用6.0毫米的棒连接。以随机方式检查三种不同交联结构在拔出和屈伸压缩试验中结构失效所需的力:非交联对照、传统交联和穿过棘突基部的交联。强度数据的统计比较采用Student's -检验进行分析。
结果
棘突组结构失效所需的拔出力明显大于对照组(=0.036)。在拔出试验中,对照组和交联组之间、交联组和棘突组之间均未发现差异。在屈伸压缩试验中,棘突组结构失效所需的力明显大于对照组和交联组(分别为<0.001和=0.003)。然而,对照组和交联组之间没有差异。
结论
一种新型交联结构,其交联装置穿过棘突基部,与非交联结构相比,在拔出和屈伸压缩试验中增加了机械阻力。与传统交联结构相比,这种结构在屈伸压缩试验中对中柱损伤提供了更大的抵抗力。
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