椎间盘核在高加载速率下的力学功能。

Mechanical Function of the Nucleus Pulposus of the Intervertebral Disc Under High Rates of Loading.

机构信息

Department of Bioengineering, Imperial College London, UK.

Biomechanics and Spine Research Group, Queensland University of Technology, Brisbane, Australia.

出版信息

Spine (Phila Pa 1976). 2019 Aug 1;44(15):1035-1041. doi: 10.1097/BRS.0000000000003092.

DOI:10.1097/BRS.0000000000003092

PMID:31095121

Abstract

STUDY DESIGN

Bovine motion segments were used to investigate the high-rate compression response of intervertebral discs (IVD) before and after depressurising the nucleus pulposus (NP) by drilling a hole through the cranial endplate into it.

OBJECTIVE

To investigate the effect of depressurising the NP on the force-displacement response, and the energy absorption in IVDs when compressed at high strain rates.

SUMMARY OF BACKGROUND DATA

The mechanical function of the gelatinous NP located in the center of the IVDs of the spine is unclear. Removal of the NP has been shown to affect the direction of bulge of the inner anulus fibrosus (AF), but at low loading rates removal of the NP pressure does not affect the IVD's stiffness. During sports or injurious events, IVDs are commonly exposed to high loading rates, however, no studies have investigated the mechanical function of the NP at these rates.

METHODS

Eight bovine motion segments were used to quantify the change in pressure caused by a hole drilled through the cranial endplate into the NP, and eight segments were used to investigate the high-rate response before and after a hole was drilled into the NP.

RESULTS

The hole caused a 28.5% drop in the NP pressure. No statistically significant difference was seen in peak force, peak displacement, or energy-absorption of the intact, and depressurized NP groups under impact loading. The IVDs absorbed 72% of the input energy, and there was no rate dependency in the percentage energy absorbed.

CONCLUSION

These results demonstrate that the NP pressure does not affect the transfer of load through, or energy absorbed by, the IVD at high loading rates and the AF, rather than the NP, may play the most important role in transferring load, and absorbing energy at these rates. This should be considered when attempting surgically to restore IVD function.

LEVEL OF EVIDENCE

N/A.

摘要

研究设计

本研究使用牛的运动节段，通过在颅端板上钻孔进入髓核（NP）来研究 NP 减压前后椎间盘（IVD）的高速压缩响应。

目的

研究 NP 减压对 IVD 在高速应变率下压缩时的力-位移响应和能量吸收的影响。

背景资料概要

位于脊柱 IVD 中心的凝胶状 NP 的机械功能尚不清楚。已表明去除 NP 会影响内纤维环（AF）的隆起方向，但在低加载速率下，去除 NP 压力不会影响 IVD 的刚度。在运动或受伤事件中，IVD 通常会受到高加载速率的影响，但没有研究调查 NP 在这些速率下的机械功能。

方法

使用 8 个牛运动节段来量化通过颅端板钻入 NP 引起的压力变化，使用 8 个节段来研究 NP 钻入前后的高速响应。

结果

钻孔导致 NP 压力下降 28.5%。在冲击加载下，完整和减压 NP 组的峰值力、峰值位移或能量吸收没有统计学上的显著差异。IVD 吸收了 72%的输入能量，能量吸收的百分比没有速率依赖性。

结论

这些结果表明，NP 压力不会影响 IVD 在高速加载率下的负荷传递或能量吸收，而在这些速率下，AF 而不是 NP 可能在传递负荷和吸收能量方面发挥最重要的作用。在试图通过手术恢复 IVD 功能时，应考虑到这一点。

证据水平

N/A。

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椎间盘核在高加载速率下的力学功能。

Mechanical Function of the Nucleus Pulposus of the Intervertebral Disc Under High Rates of Loading.

机构信息

出版信息

STUDY DESIGN

OBJECTIVE

SUMMARY OF BACKGROUND DATA

METHODS

RESULTS

CONCLUSION

LEVEL OF EVIDENCE

研究设计

目的

背景资料概要

方法

结果

结论

证据水平

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