University of Maryland Medical Center, Department of Orthopaedics, 110 S. Paca St, 6th Floor. Suite 300, Baltimore MD 21201-1642, USA.
Virginia Spine Institue, 11800 Sunrise Vallley Drive, Reston Virginia, 20191.
Spine J. 2019 Mar;19(3):545-551. doi: 10.1016/j.spinee.2018.09.002. Epub 2018 Sep 7.
Adjacent segment disease (ASD) is a well-known complication after lumbar fusion. Lumbar lateral interbody fusion (LLIF) may provide an alternative method of treatment for ASD while avoiding the morbidity associated with revision surgery through a traditional posterior approach. This is the first biomechanical study to evaluate the stability of lateral-based constructs for treating ASD in existing multilevel fusion model.
We aimed to evaluate the biomechanical stability of anterior column reconstruction through the less invasive lateral-based interbody techniques compared with traditional posterior spinal fusion for the treatment of ASD in existing multilevel fusion.
STUDY DESIGN/SETTING: Cadaveric biomechanical study of laterally based interbody strategies for treating ASD.
Eighteen fresh-frozen cadaveric specimens were nondestructively loaded in flexion, extension, and lateral bending. The specimens were randomized into three different groups according to planned posterior spinal instrumented fusion (PSF): group 1: L5-S1, group 2: L4-S1, and group 3: L3-S1. In each group, ASD was considered the level cranial to the upper-instrumented vertebrae (UIV). After testing the intact spine, each specimen underwent PSF representing prior fusion in the ASD model. The adjacent segment for each specimen then underwent (1) Stand-alone LLIF, (2) LLIF + plate, (3) LLIF + single screw rod (SSR) anterior instrumentation, and (4) LLIF + traditional posterior extension of PSF. In all conditions, three-dimensional kinematics were tracked, and range of motion (ROM) was calculated for the comparisons.
ROM results were expressed as a percentage of the intact spine ROM. LLIF effectively reduces ROM in all planes of ROM. Supplementation of LLIF with plate or SSR provides further stability as compared with stand-alone LLIF. Expansion of posterior instrumentation provides the most substantial stability in all planes of ROM (p <.05). All constructs demonstrated a consistent trend of reduction in ROM between all the groups in all bending motions.
This biomechanical study suggests potential promise in exploring LLIF as an alternative treatment of ASD but reinforces previous studies' findings that traditional expansion of posterior instrumentation provides the most biomechanically stable construct.
邻近节段疾病(ASD)是腰椎融合术后的一种常见并发症。腰椎侧方椎间融合术(LLIF)可能为 ASD 提供一种替代治疗方法,同时避免传统后路翻修手术相关的发病率。这是第一项评估在现有多节段融合模型中治疗 ASD 的基于侧方构建物稳定性的生物力学研究。
我们旨在通过微创基于侧方的椎间技术评估与传统后路脊柱融合术相比,在治疗现有多节段融合中的 ASD 时,前柱重建的生物力学稳定性。
研究设计/设置:治疗 ASD 的基于侧方的椎间策略的尸体生物力学研究。
18 个新鲜冷冻尸体标本在屈伸和侧屈方向进行无损加载。标本根据计划的后路脊柱内固定融合(PSF)随机分为三组:组 1:L5-S1,组 2:L4-S1,组 3:L3-S1。每组中,ASD 被认为是上固定椎(UIV)上方的节段。在测试完整脊柱后,每个标本都进行了 ASD 模型中的 PSF 代表先前的融合。然后对每个标本的相邻节段进行以下操作:(1)单纯 LLIF,(2)LLIF+板,(3)LLIF+单螺钉棒(SSR)前路内固定,以及(4)LLIF+传统 PSF 的后路扩展。在所有条件下,都进行了三维运动学跟踪,并计算了运动范围(ROM)进行比较。
ROM 结果表示为完整脊柱 ROM 的百分比。LLIF 有效地降低了所有平面的 ROM。与单纯 LLIF 相比,LLIF 加板或 SSR 提供了进一步的稳定性。后路器械的扩展提供了所有平面 ROM 中最显著的稳定性(p<.05)。所有构建物在所有弯曲运动中均表现出在所有组之间 ROM 降低的一致趋势。
这项生物力学研究表明,探索 LLIF 作为 ASD 的替代治疗方法具有潜在的前景,但也强化了之前研究的发现,即传统的后路器械扩展提供了最具生物力学稳定性的构建物。
