颈椎前路固定：使用静态和动态钢板的负荷分担及稳定性分析

Anterior cervical fixation: analysis of load-sharing and stability with use of static and dynamic plates.

作者信息

Brodke Darrel S, Klimo Paul, Bachus Kent N, Braun John T, Dailey Andrew T

机构信息

Department of Orthopaedics and the Orthopaedic Research Laboratory, University of Utah Orthopaedic Center, Salt Lake City, UT 84108, USA.

出版信息

J Bone Joint Surg Am. 2006 Jul;88(7):1566-73. doi: 10.2106/JBJS.E.00305.

DOI:10.2106/JBJS.E.00305

PMID:16818983

Abstract

BACKGROUND

Anterior plates provide stability following decompression and fusion of the cervical spine. Various plate designs have emerged, and they include static plates with fixed-angle screws, rotationally dynamic plates that allow the screws to toggle in the plate, and translationally dynamic plates that allow the screws to both toggle and translate vertically. The goal of this study was to document the effects of plate design following a single-level corpectomy and placement of a full-length strut graft and the effects following 10% subsidence of the graft.

METHODS

A total of twenty-one cadaveric cervical spines (C2-T1) were randomized into three treatment groups and were tested for initial range of motion. A C5 corpectomy was performed, reconstruction was done with a full-length interbody spacer containing a load-cell, and an anterior cervical plate was applied. Load-sharing data were recorded with incremental axial loads. The range of motion was measured with +/- 2.5 Nm of torque in flexion-extension, lateral bending, and axial rotation. Then, the total length of the interbody spacer was reduced by 10% to simulate subsidence, and load-sharing and the range of motion were retested.

RESULTS

With the full-length interbody spacer, there were no significant differences in the abilities of the constructs to share load or limit motion. Following shortening of the interbody spacer, the static plate construct lost nearly 70% of its load-sharing capability, while neither of the dynamic plate constructs lost load-sharing capabilities. Also, the static plate construct allowed significantly more motion in flexion-extension following simulated subsidence than did either of the dynamic plate constructs (p < 0.05).

CONCLUSIONS

Although all of the tested anterior cervical plating systems provide similar load-sharing and stiffness following initial placement of the interbody spacer, the static plate system lost its ability to share load and limit motion following simulated subsidence of the interbody spacer. Both dynamic plate systems maintained load-sharing and stiffness despite simulated subsidence.

CLINICAL RELEVANCE

This study provides an improved understanding of the immediate performance of anterior cervical fusion surgery with plate fixation.

摘要

背景

前路钢板可在颈椎减压融合术后提供稳定性。出现了各种钢板设计，包括带有固定角度螺钉的静态钢板、允许螺钉在钢板内摆动的旋转动态钢板以及允许螺钉既能摆动又能垂直平移的平移动态钢板。本研究的目的是记录单节段椎体次全切除并置入全长支撑植骨后钢板设计的影响，以及植骨下沉10%后的影响。

方法

总共21个尸体颈椎（C2-T1）被随机分为三个治疗组，并测试其初始活动范围。进行C5椎体次全切除，用包含测力传感器的全长椎间融合器进行重建，并应用颈椎前路钢板。随着轴向负荷增加记录负荷分担数据。在屈伸、侧屈和轴向旋转时，用±2.5 Nm的扭矩测量活动范围。然后，将椎间融合器的总长度缩短10%以模拟下沉，并重新测试负荷分担和活动范围。

结果

使用全长椎间融合器时，各结构在负荷分担或限制活动能力方面无显著差异。椎间融合器缩短后，静态钢板结构失去了近70%的负荷分担能力，而动态钢板结构均未失去负荷分担能力。此外，模拟下沉后，静态钢板结构在屈伸时允许的活动明显多于任何一种动态钢板结构（p<0.05）。

结论

尽管所有测试的颈椎前路钢板系统在椎间融合器初始置入后提供相似的负荷分担和刚度，但在模拟椎间融合器下沉后，静态钢板系统失去了负荷分担和限制活动的能力。两种动态钢板系统尽管模拟下沉但仍保持负荷分担和刚度。

临床意义

本研究有助于更好地理解颈椎前路融合钢板固定手术的即时性能。

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颈椎前路固定：使用静态和动态钢板的负荷分担及稳定性分析

Anterior cervical fixation: analysis of load-sharing and stability with use of static and dynamic plates.

作者信息

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

CLINICAL RELEVANCE

背景

方法

结果

结论

临床意义

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