退行性腰椎滑脱的体外模型。
An in vitro model of degenerative lumbar spondylolisthesis.
机构信息
Department of Orthopaedics,International Collaboration on Repair Discoveries, University of British Columbia, Vancouver, BC, Canada.
出版信息
Spine (Phila Pa 1976). 2013 Jun 15;38(14):E870-7. doi: 10.1097/BRS.0b013e3182945897.
STUDY DESIGN
A biomechanical human cadaveric study.
OBJECTIVE
To create a biomechanical model of low-grade degenerative lumbar spondylolisthesis (DLS), defined by anterior listhesis, for future testing of spinal instrumentation.
SUMMARY OF BACKGROUND DATA
Current spinal implants are used to treat a multitude of conditions that range from herniated discs to degenerative diseases. The optimal stiffness of these instrumentation systems for each specific spinal condition is unknown. Ex vivo models representing degenerative spinal conditions are scarce in the literature. A model of DLS for implant testing will enhance our understanding of implant-spine behavior for specific populations of patients.
METHODS
Four incremental surgical destabilizations were performed on 8 lumbar functional spinal units. The facet complex and intervertebral disc were targeted to represent the tissue changes associated with DLS. After each destabilization, the specimen was tested with: (1) applied shear force (-50 to 250 N) with a constant axial compression force (300 N) and (2) applied pure moments in flexion-extension, lateral bending and axial rotation (±5 Nm). Relative motion between the 2 vertebrae was tracked with a motion capture system. The effect of specimen condition on intervertebral motion was assessed for shear and flexibility testing.
RESULTS
Shear translation increased, specimen stiffness decreased and range of motion increased with specimen destabilization (P < 0.0002). A mean anterior translation of 3.1 mm (SD 1.1 mm) was achieved only after destabilization of both the facet complex and disc. Of the 5 specimen conditions, 3 were required to achieve grade 1 DLS: (1) intact, (3) a 4-mm facet gap, and (5) a combined nucleus and annulus injury.
CONCLUSION
Destabilization of both the facet complex and disc was required to achieve anterior listhesis of 3.1 mm consistent with a grade 1 DLS under an applied shear force of 250 N. Sufficient listhesis was measured without radical specimen resection. Important anatomical structures for supporting spinal instrumentation were preserved such that this model can be used in future to characterize behavior of novel instrumentation prior to clinical trials.
研究设计
一项生物力学人体尸体研究。
目的
创建一个由前滑移定义的低级退行性腰椎滑脱(DLS)的生物力学模型,以便将来对脊柱器械进行测试。
背景资料概要
目前的脊柱植入物用于治疗从椎间盘突出到退行性疾病等多种病症。这些器械系统对于每种特定脊柱病症的最佳刚度尚不清楚。代表退行性脊柱病症的离体模型在文献中很少见。用于植入物测试的 DLS 模型将增强我们对特定患者人群的植入物-脊柱行为的理解。
方法
在 8 个腰椎功能单位上进行了 4 次递增的外科不稳定化。针对小关节复合体和椎间盘进行靶向处理,以代表与 DLS 相关的组织变化。在每次不稳定化后,标本进行以下测试:(1)在施加 300N 的轴向压缩力的同时施加-50 至 250N 的剪切力,(2)在屈伸、侧屈和轴向旋转方向施加±5Nm 的纯力矩。使用运动捕捉系统跟踪 2 个椎体之间的相对运动。评估标本状态对剪切和柔韧性测试的椎间运动的影响。
结果
随着标本不稳定化,剪切位移增加,标本刚度降低,运动范围增加(P<0.0002)。仅在小关节复合体和椎间盘均不稳定化后才能达到 3.1mm(标准差 1.1mm)的平均前滑移。在 5 种标本状态中,有 3 种需要达到 1 级 DLS:(1)完整,(3)4mm 小关节间隙,和(5)核和环损伤的组合。
结论
在施加 250N 的剪切力下,需要同时使小关节复合体和椎间盘不稳定化才能达到 3.1mm 的前滑移,与 1 级 DLS 一致。在不进行激进标本切除的情况下,测量到足够的滑移。保留了支撑脊柱器械的重要解剖结构,以便将来在临床试验之前使用该模型来描述新型器械的行为。
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