Metzger Melodie F, Robinson Samuel T, Maldonado Ruben C, Rawlinson Jeremy, Liu John, Acosta Frank L
Orthopedic Biomechanics Laboratory, Department of Orthopedic Surgery, Cedars-Sinai Medical Center, 8700 Beverly Blvd, Davis Building Rm 6006, Los Angeles, CA 90048, USA.
Orthopedic Biomechanics Laboratory, Department of Orthopedic Surgery, Cedars-Sinai Medical Center, 8700 Beverly Blvd, Davis Building Rm 6006, Los Angeles, CA 90048, USA.
Spine J. 2017 Jul;17(7):1004-1011. doi: 10.1016/j.spinee.2017.03.005. Epub 2017 Mar 18.
Surgical treatment of symptomatic adjacent segment disease (ASD) typically involves extension of previous instrumentation to include the newly affected level(s). Disruption of the incision site can present challenges and increases the risk of complication. Lateral-based interbody fusion techniques may provide a viable surgical alternative that avoids these risks. This study is the first to analyze the biomechanical effect of adding a lateral-based construct to an existing fusion.
The study aimed to determine whether a minimally invasive lateral interbody device, with and without supplemental instrumentation, can effectively stabilize the rostral segment adjacent to a two-level fusion when compared with a traditional posterior revision approach.
STUDY DESIGN/SETTING: This is a cadaveric biomechanical study of lateral-based interbody strategies as add-on techniques to an existing fusion for the treatment of ASD.
Twelve lumbosacral specimens were non-destructively loaded in flexion, extension, lateral bending, and torsion. Sequentially, the tested conditions were intact, two-level transforaminal lumbar interbody fusion (TLIF) (L3-L5), followed by lateral lumbar interbody fusion procedures at L2-L3 including interbody alone, a supplemental lateral plate, a supplemental spinous process plate, and then either cortical screw or pedicle screw fixation. A three-level TLIF was the final instrumented condition. In all conditions, three-dimensional kinematics were tracked and range of motion (ROM) was calculated for comparisons. Institutional funds (<$50,000) in support of this work were provided by Medtronic Spine.
The addition of a lateral interbody device superadjacent to a two-level fusion significantly reduced motion in flexion, extension, and lateral bending (p<.05). Supplementing with a lateral plate further reduced ROM during lateral bending and torsion, whereas a spinous process plate further reduced ROM during flexion and extension. The addition of posterior cortical screws provided the most stable lateral lumbar interbody fusion construct, demonstrating ROM comparable with a traditional three-level TLIF.
The data presented suggest that a lateral-based interbody fusion supplemented with additional minimally invasive instrumentation may provide comparable stability with a traditional posterior revision approach without removal of the existing two-level rod in an ASD revision scenario.
有症状的相邻节段疾病(ASD)的手术治疗通常包括将先前的内固定器械延长至新受累节段。切口部位的破坏可能带来挑战并增加并发症风险。基于外侧的椎间融合技术可能提供一种可行的手术替代方案,可避免这些风险。本研究首次分析了在现有融合基础上增加基于外侧的结构的生物力学效应。
本研究旨在确定与传统后路翻修方法相比,一种微创外侧椎间装置在有无辅助内固定器械的情况下,能否有效稳定与双节段融合相邻的头侧节段。
研究设计/地点:这是一项尸体生物力学研究,研究基于外侧的椎间策略作为现有融合治疗ASD的附加技术。
对12个腰骶椎标本进行无损的前屈、后伸、侧弯和扭转加载。依次测试的条件为完整状态、双节段经椎间孔腰椎椎间融合术(TLIF)(L3-L5),随后在L2-L3进行腰椎外侧椎间融合手术,包括单纯椎间融合、附加外侧钢板、附加棘突钢板,然后进行皮质骨螺钉或椎弓根螺钉固定。最终的内固定条件为三节段TLIF。在所有条件下,跟踪三维运动学并计算活动范围(ROM)以进行比较。美敦力脊柱公司提供了支持本研究的机构资金(<50,000美元)。
在双节段融合上方添加外侧椎间装置可显著减少前屈、后伸和侧弯时的运动(p<0.05)。附加外侧钢板可进一步减少侧弯和扭转时的ROM,而棘突钢板可进一步减少前屈和后伸时的ROM。添加后路皮质骨螺钉可提供最稳定的腰椎外侧椎间融合结构,其ROM与传统三节段TLIF相当。
所呈现的数据表明,在ASD翻修情况下,在基于外侧的椎间融合基础上补充额外的微创内固定器械,可能提供与传统后路翻修方法相当的稳定性,且无需移除现有的双节段棒。
