- 作者:Qi Liu1 ; Qunfeng Guo1 ; Jun Yang1 ; Peng Zhang1 ; Tianming Xu1 ; Xiaofei Cheng1 ; Jinshui Chen1 ; 2 ; Huapeng Guan1 ; Bin Ni1 ; nibin99@sohu.com" class="auth_mail" title="E-mail the corresponding author
- 关键词:Atlantoaxial instability ; Atlantoaxial fixation ; Biomechanics ; Cervical alignment ; Intradiscal pressure ; Kinematics ; Cervical spine
- 刊名:World Neurosurgery
- 出版年:2016
- 出版时间:March 2016
- 年:2016
- 卷:87
- 期:Complete
- 页码:521-528
- 全文大小:4501 K
Methods
We simulated three-dimensional cervical motions on 8 human specimens with C1-C2 fixed in 3 different angles (neutral position, neutral position −10°, neutral position +10°) following intact analysis in the material test system. The ROM changes of each motion segment and the IDP changes of 4 subaxial motion segments (C2-C3, C3-C4, C4-C5, and C5-C6) were monitored.
Results
ROM change patterns at all subaxial segments were similar. Fixed C1-C2 led to a significant ROM increase relative to the intact condition during flexion/extension testing. A larger C1-C2 angle (neutral position +10°) caused an additional ROM increase during flexion, whereas a smaller C1-C2 angle (neutral position −10°) induced a further ROM increase during extension. Axial rotation testing revealed the most striking and similar ROM increases in the instrumented groups relative to the intact group. Lateral bending testing did not reveal significant ROM change between the instrumented groups and the intact group. For IDP analysis, C1-C2 fixed in a larger angle (neutral position +10°) caused significant IDP increases at the C2-C3, C3-C4, and C4-C5 levels during flexion.
Conclusions
To maintain a physiologic sagittal alignment of subaxial cervical spine, C1-C2 should be fixed in the neutral position or a relatively smaller angle instead of a more lordotic position.