Quarrington Ryan D, Bauze Robert, Jones Claire F
Adelaide Spinal Research Group, Centre for Orthopaedic & Trauma Research, Faculty of Health and Medical Sciences The University of Adelaide Adelaide South Australia Australia.
Adelaide Medical School The University of Adelaide Adelaide South Australia Australia.
JOR Spine. 2024 May 27;7(2):e1336. doi: 10.1002/jsp2.1336. eCollection 2024 Jun.
The first experimental study to produce cervical facet dislocation (CFD) in cadaver specimens captured the vertebral motions and axial forces that are important for understanding the injury mechanics. However, these data were not reported in the original manuscript, nor been presented in the limited subsequent studies of experimental CFD. Therefore, the aim of this study was to re-examine the analog data from the first experimental study to determine the local and global spinal motions, and applied axial force, at and preceding CFD.
In the original study, quasistatic axial loading was applied to 14 cervical spines by compressing them between two metal plates. Specimens were fixed caudally via a steel spindle positioned within the spinal canal and a bone pin through the inferior-most vertebral body. Global rotation of the occiput was restricted but its anterior translation was unconstrained. The instant of CFD was identified on sagittal cineradiograph films ( = 10), from which global and intervertebral kinematics were also calculated. Corresponding axial force data ( = 6) were extracted, and peak force and force at the instant of injury were determined.
CFD occurred in eight specimens, with an intervertebral flexion angle of 34.8 ± 5.6 degrees, and a 3.1 ± 1.9 mm increase in anterior translation, at the injured level. For seven specimens, CFD was produced at the level of transition from upper neck lordosis to lower neck kyphosis. Five specimens with force data underwent CFD at 545 ± 147 N, preceded by a peak axial force (755 ± 233 N) that appeared to coincide with either fracture or soft tissue failure.
Re-examining this rich dataset has provided quantitative evidence that small axial compression forces, combined with anterior eccentricity and upper neck extension, can cause flexion and shear in the lower neck, leading to soft tissue rupture and CFD.
首次在尸体标本上产生颈椎小关节脱位(CFD)的实验研究记录了对于理解损伤机制很重要的椎体运动和轴向力。然而,这些数据在原始手稿中未被报告,在随后有限的实验性CFD研究中也未呈现。因此,本研究的目的是重新审视首次实验研究中的模拟数据,以确定CFD发生时及发生前局部和整体脊柱的运动以及施加的轴向力。
在原始研究中,通过在两个金属板之间压缩14个颈椎来施加准静态轴向载荷。标本通过位于椎管内的钢轴和穿过最下椎体的骨钉在尾侧固定。枕骨的整体旋转受到限制,但其向前平移不受约束。在矢状位动态X线片(n = 10)上确定CFD的瞬间,还从这些片子上计算整体和椎间运动学。提取相应的轴向力数据(n = 6),并确定峰值力和损伤瞬间的力。
8个标本发生了CFD,损伤节段的椎间屈曲角度为34.8±5.6度,向前平移增加3.1±1.9毫米。7个标本在从颈上凸向颈下凹的过渡水平产生了CFD。5个有力数据的标本在545±147 N时发生CFD,之前的轴向力峰值(755±233 N)似乎与骨折或软组织失效同时出现。
重新审视这个丰富的数据集提供了定量证据,即小的轴向压缩力,结合前侧偏心和颈上伸展,可导致颈下屈曲和剪切,导致软组织破裂和CFD。
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