完整纤维环下经椎弓根髓核切除术的生物力学评估
Biomechanical Evaluation of Transpedicular Nucleotomy With Intact Annulus Fibrosus.
作者信息
Russo Fabrizio, Hartman Robert A, Bell Kevin M, Vo Nam, Sowa Gwendolyn A, Kang James D, Vadalà Gianluca, Denaro Vincenzo
机构信息
Department of Orthopedic and Traumatology, University Campus BioMedico of Rome, Rome, Italy.
Department of Physical Medicine and Rehabilitation, University of Pittsburgh, Pittsburgh, USA.
出版信息
Spine (Phila Pa 1976). 2017 Feb 15;42(4):E193-E201. doi: 10.1097/BRS.0000000000001762.
STUDY DESIGN
Biomechanical testing of partially nucleotomized ovine cadaveric spines.
OBJECTIVE
To explore how the nucleus pulposus (NP) affects the biomechanical behavior of the intervertebral disc (IVD) by performing a partial nucleotomy via the transpedicular approach.
SUMMARY OF BACKGROUND DATA
Mechanical loading represents a crucial part of IVD homeostasis. However, traditional regenerative strategies require violation of the annulus fibrosus (AF) resulting in significant alteration of joint mechanics. The transpedicular nucleotomy represents a suitable method to create a cavity into the NP, as a model to study IVD regeneration with intact AF.
METHODS
A total of 30 ovine-lumbar- functional spinal units (FSUs) (L1-L6) randomly assigned to 5 groups: control; transpedicular tunnel (TT); TT + polymethylmethacrylate (PMMA) to repair the bone tunnel; nucleotomy; nucleotomy + PMMA. Flexion/extension, lateral-bending, and axial-rotation were evaluated under adaptive displacement control. Axial compression was applied for 15 cycles of preconditioning followed by 1 hour of constant compression. Viscoelastic behavior was modeled and parameterized.
RESULTS
TT has minimal effects on rotational biomechanics. The nucleotomy increases ROM and neutral zone (NZ) displacement width whereas decreasing NZ stiffness. TT + PMMA has small effects in terms of ROM. Nucleotomy + PMMA brings ROM back to the control, increases NZ stiffness, and decreases NZ displacement width. The nucleotomy tends to increase the rate of early creep. TT reduces early and late damping. The use of PMMA increased late elastic stiffness (S2) and reduced viscous damping (η2) culminating in faster resolution of creep.
CONCLUSION
Biomechanical properties of NP are crucial for IVD repair. This study demonstrated that TT does not affect rotational stability whereas partial nucleotomy with intact AF induce rotational instability, highlighting the central role of NP in early stages of IDD. Therefore, this model represents a successful platform to validate and optimize disc regeneration strategies.
LEVEL OF EVIDENCE
N/A.
研究设计
对部分髓核摘除的绵羊尸体脊柱进行生物力学测试。
目的
通过经椎弓根入路进行部分髓核摘除术,探讨髓核(NP)如何影响椎间盘(IVD)的生物力学行为。
背景数据总结
机械负荷是椎间盘内环境稳定的关键部分。然而,传统的再生策略需要破坏纤维环(AF),从而导致关节力学的显著改变。经椎弓根髓核摘除术是一种在NP中创建腔隙的合适方法,可作为研究完整AF情况下IVD再生的模型。
方法
总共30个绵羊腰椎功能脊柱单元(FSUs)(L1-L6)随机分为5组:对照组;椎弓根隧道(TT)组;TT + 聚甲基丙烯酸甲酯(PMMA)修复骨隧道组;髓核摘除组;髓核摘除 + PMMA组。在自适应位移控制下评估前屈/后伸、侧屈和轴向旋转。施加轴向压缩进行15个周期的预处理,然后进行1小时的持续压缩。对粘弹性行为进行建模和参数化。
结果
TT对旋转生物力学影响最小。髓核摘除增加了活动度(ROM)和中性区(NZ)位移宽度,而降低了NZ刚度。TT + PMMA对ROM影响较小。髓核摘除 + PMMA使ROM恢复到对照组水平,增加了NZ刚度,并减小了NZ位移宽度。髓核摘除倾向于增加早期蠕变率。TT降低了早期和晚期阻尼。PMMA的使用增加了晚期弹性刚度(S2)并降低了粘性阻尼(η2),最终使蠕变更快消退。
结论
NP的生物力学特性对IVD修复至关重要。本研究表明,TT不影响旋转稳定性,而完整AF的部分髓核摘除会导致旋转不稳定,突出了NP在椎间盘退变(IDD)早期阶段的核心作用。因此,该模型是验证和优化椎间盘再生策略的成功平台。
证据水平
无。
Zotero 插件