Quigley Kevin J, Alander Dirk H, Bledsoe John Gary
Department of Orthopaedic Surgery, Saint Louis University Health Sciences, Saint Louis University, St Louis, MO, USA.
J Spinal Disord Tech. 2008 Aug;21(6):442-7. doi: 10.1097/BSD.0b013e3181568637.
This study is a biomechanical analysis of intervertebral cage placement, using a biomechanical model that has the appropriate matching geometry of the lumbar spine at the level of L4-L5 based upon prior morphometric studies.
The goal of this in vitro biomechanical analysis of interbody cages is to determine the effect of interbody cage position on the mechanics of posterior spinal instrumentation. This biomechanical analysis can potentially be used to guide surgical technique for placement of interbody cage devices.
Lumbar interbody spinal fusion cages are increasingly being used to promote spinal fusion and improve sagittal alignment in patients with degenerative disk disease. The transforaminal approach for placement of these cages has become popular, although the actual position of the cage that will provide optimal mechanical support in the intervertebral space is not known.
Leopard carbon fiber interbody cages (DepuySpine, Raynham, MA) were placed in a spinal fusion model simulating the L4-L5 disk space in one of 3 positions-anterior, middle, or anterolateral. We tested 5 constructs in each of the 3 positions, applying cyclic axial loads of 500 N at a rate of 4 Hz for 100,000 cycles. Strain on the posterior instrumentation and displacement of the cages was measured at periodic intervals. Load to failure of each construct was tested after 100,000 cycles were complete.
Statistical analysis of biomechanical indicators show more strain in the anterolateral position as compared with the anterior position (P=0.002) and middle position (P=0.02). No difference was noted between anterior and middle positions (P=1.00). Interval analysis reveals differences in strain at 500 cycles in anterior versus anterolateral (P=0.01) and middle versus anterolateral (P=0.02). At 10,000 cycles, anterolateral strain was significantly higher (P=0.02) than anterior. No significant difference in strain was noted at 50,000 or 100,000 cycles between any of the positions. No significant differences were noted in displacement of the cages between each of the positions. Ultimate load to failure was lower (nonsignificant) in the anterolateral versus anterior position (P=0.06), but no difference was noted between anterior versus middle (P=0.57) or anterolateral versus middle (P=0.69) positions. Linear regression analysis of load-displacement curves shows significance at 500 cycles (P=0.02), approaching significance at 10,000 cycles (P=0.07), and no significant difference at 50,000 (P=0.28) or 100,000 (P=0.28) cycles.
Positioning of interbody cages in an offset position shows higher strain upon posterior instrumentation than a central position, and quicker load to failure than an anteriorly placed cage. Biomechanical studies using shear loading, and testing of adjacent spinal levels, are necessary to further elucidate the biomechanical consequences of variable positioning of interbody cages.
本研究是对椎间融合器植入的生物力学分析,使用的生物力学模型基于先前的形态测量学研究,在L4 - L5水平具有与腰椎相匹配的合适几何形状。
本项椎间融合器体外生物力学分析的目的是确定椎间融合器位置对后路脊柱内固定力学的影响。这种生物力学分析可能用于指导椎间融合器装置植入的手术技术。
腰椎椎间融合器越来越多地用于促进脊柱融合并改善退行性椎间盘疾病患者的矢状位排列。尽管尚不清楚在椎间间隙中提供最佳机械支撑的融合器的实际位置,但经椎间孔途径植入这些融合器已变得流行。
将豹纹碳纤维椎间融合器(DepuySpine,马萨诸塞州雷纳姆)置于模拟L4 - L5椎间盘间隙的脊柱融合模型中的3个位置之一——前位、中位或前外侧位。我们在3个位置中的每个位置测试5个结构,以4 Hz的频率施加500 N的循环轴向载荷,持续100,000次循环。定期测量后路内固定器上的应变和融合器的位移。在完成100,000次循环后测试每个结构的破坏载荷。
生物力学指标的统计分析显示,与前位(P = 0.002)和中位(P = 0.02)相比,前外侧位的应变更大。前位和中位之间未发现差异(P = 1.00)。区间分析显示,在前位与前外侧位(P = 0.01)以及中位与前外侧位(P = 0.02)的500次循环时应变存在差异。在10,000次循环时,前外侧位的应变显著高于前位(P = 0.02)。在50,000次或100,000次循环时,各位置之间的应变未发现显著差异。各位置之间融合器的位移未发现显著差异。前外侧位与前位相比,最终破坏载荷较低(无显著性差异)(P = 0.06),但前位与中位(P = 0.57)或前外侧位与中位(P = 0.69)之间未发现差异。载荷 - 位移曲线的线性回归分析显示在500次循环时具有显著性(P = 0.02),在10,000次循环时接近显著性(P = 0.07),在50,000次(P = 0.28)或100,000次(P = 0.28)循环时无显著差异。
椎间融合器偏位放置时,后路内固定器上的应变高于中心位置,且破坏载荷比前置融合器更快。使用剪切载荷进行生物力学研究以及对相邻脊柱节段进行测试,对于进一步阐明椎间融合器不同放置位置的生物力学后果是必要的。
