McAfee Paul C, Cunningham Bryan, Dmitriev Anton, Hu Niabin, Woo Kim Seok, Cappuccino Andy, Pimenta Luiz
St. Joseph Hospital, Scoliosis and Spine Center, Towson, MD 21204, USA.
Spine (Phila Pa 1976). 2003 Oct 15;28(20):S176-85. doi: 10.1097/01.BRS.0000092219.28382.0C.
Benchtop cadaveric biomechanical comparative testing and caprine animal model in vivo implantation.
To evaluate the role of the posterior longitudinal ligament in cervical arthroplasty and to understand the relative contribution of this ligament in nonfusion applications.
Rauschning refers to the posterior longitudinal ligament as "The Kleenex Ligament" due to its apparent anatomic insignificance. White and Panjabi found the posterior longitudinal ligament ranked only fourth in importance in tensile load-to-failure biomechanical testing. In the postoperative situation following anterior cervical diskectomy fusion, posterior longitudinal ligament integrity is overlooked by physicians because the entire disc space usually fuses into a homogeneous block of bone.
This biomechanical study was undertaken to determine the relative importance of the posterior longitudinal ligament following two different degrees of anterior decompression, anterior disc replacement, and anterior arthrodesis procedures.
A total of seven fresh frozen human cadaveric cervical spines (C3-C7) (mean age 68 +/- 19 years) were used for biomechanical testing. Each vertebra was equipped with three non-colinear light emitting diodes designed for detection by an optoelectronic motion measurement system (3020 Optotract System). To determine the multidirectional flexibility, six pure moments (flexion, extension, right + left lateral bending, right + left axial rotation) and axial compression were applied using a servohydraulic 858 Bionix testing device configured with a six-degree-of-freedom spine simulator. Range of motion was defined as the peak displacement from the initial neutral position to the maximum load, whereas the neutral zone represents the motion from the initial neutral position to the unloaded position at the beginning of the third cycle. Seven groups of (N = 7 each) constructs at C5-C6 were: 1) intact "native" C5-C6 level; 2) anterior diskectomy (posterior longitudinal ligament intact); 3) a Low Profile Porous Coated Motion cervical disc replacement; 4) posterior longitudinal ligament resected; 5) Porous Coated Motion cervical disc replacement fixed with anterior flanges and screws; 6) tricortical structural allograft; and 7) an anterior cervical translational plate + allograft. The caprine model was evaluated for suitability as an animal model with 12 goats undergoing C3-C4 anterior cervical Porous Coated Motion disc replacement.
Group 2 (anterior diskectomy alone) was significantly more stable than Group 4 (anterior diskectomy + posterior longitudinal ligament resection) in flexion-extension, 18.7 +/- 4.76 degrees versus 24.8 +/- 4.42 degrees (P < 0.05) and in lateral bending, 5.9 +/- 1.79 degrees versus 10.7 +/- 2.8 degrees (P < 0.05). The comparison for the two conditions for axial rotation, 10.4 +/- 13.9 degrees versus 13.9 +/- 2.7 degrees, and axial compression, 1.19 +/-.98 degrees versus 1.52 +/- 1.14 degrees, showed the same trend. Twelve goats undergoing porous coated motion cervical disc replacement had no evidence of prosthesis loosening, neurologic complications, or experienced inflammatory reactions from particulate wear debris after 6 months of implantation.
This study confirms the pivotal role of the posterior longitudinal ligament in postsurgical stability of the cervical spine following anterior diskectomy. This is because the lateral anulus, uncovertebral ligaments, and lateral capsular ligaments are stretched and plastically deformed in the surgical distraction process of restoring the disc space height following anterior surgical decompression. There should be a separate determination of the range of motion of cervical disc replacements depending of the integrity and the amount of the posterior longitudinal ligament that has been resected.
There are two basic types of total knee replacements, posterior cruciate ligament-preserving and posterior cruciate ligament-sacrificing designs. In the cervical spine, an analogous situation exists biomechanically depending on whether the posterior longitudinal ligament needs to be removed in its entirety as part of the spinal cord decompression part of the procedure--it may be helpful to conceptually differentiate between posterior longitudinal ligament-preserving and posterior longitudinal ligament-sacrificing total cervical disc replacements.
尸体标本的体外生物力学对比测试及在山羊动物模型中的体内植入。
评估后纵韧带在颈椎置换术中的作用,并了解该韧带在非融合手术中的相对贡献。
劳施宁称后纵韧带为“薄纸巾韧带”,因其在解剖学上看似无关紧要。怀特和潘贾比发现,在拉伸至断裂的生物力学测试中,后纵韧带的重要性仅排第四。在颈椎前路椎间盘切除融合术后,医生往往会忽视后纵韧带的完整性,因为整个椎间盘间隙通常会融合成一块均质的骨块。
本生物力学研究旨在确定在两种不同程度的前路减压、前路椎间盘置换及前路融合手术之后,后纵韧带的相对重要性。
共使用7具新鲜冷冻的人颈椎尸体标本(C3 - C7)(平均年龄68 ± 19岁)进行生物力学测试。每个椎体均安装了3个非共线发光二极管,用于由光电运动测量系统(3020 Optotract系统)进行检测。为测定多方向灵活性,使用配备六自由度脊柱模拟器的伺服液压858 Bionix测试装置施加6个纯力矩(前屈、后伸、右侧及左侧侧屈、右侧及左侧轴向旋转)和轴向压缩力。活动范围定义为从初始中立位置到最大负荷时的峰值位移,而中性区则代表从初始中立位置到第三个周期开始时无负荷位置的运动。C5 - C6节段的7组(每组n = 7)结构分别为:1)完整的“天然”C5 - C6节段;2)前路椎间盘切除(后纵韧带完整);3)低轮廓多孔涂层活动颈椎间盘置换;4)后纵韧带切除;5)用前路翼缘和螺钉固定的多孔涂层活动颈椎间盘置换;6)三层皮质结构同种异体骨移植;7)颈椎前路平移钢板 + 同种异体骨移植。对山羊模型进行评估,以确定其作为动物模型的适用性,12只山羊接受了C3 - C4节段的颈椎多孔涂层活动椎间盘置换。
第2组(单纯前路椎间盘切除)在屈伸活动方面明显比第4组(前路椎间盘切除 + 后纵韧带切除)更稳定,分别为18.7 ± 4.76度对24.8 ± 4.42度(P < 0.05),在侧屈活动方面,分别为5.9 ± 1.79度对10.7 ± 2.8度(P < 0.05)。两种情况在轴向旋转(分别为10.4 ± 13.9度对13.9 ± 2.7度)和轴向压缩(分别为1.19 ± 0.98度对1.52 ± 1.14度)方面的比较显示出相同趋势。12只接受多孔涂层活动颈椎间盘置换的山羊在植入6个月后,没有假体松动、神经并发症或因颗粒磨损碎屑引起炎症反应的迹象。
本研究证实了后纵韧带在颈椎前路椎间盘切除术后脊柱稳定性中的关键作用。这是因为在前路手术减压后恢复椎间盘间隙高度的手术牵张过程中,外侧纤维环、钩椎韧带和外侧关节囊韧带会被拉伸并发生塑性变形。应根据后纵韧带的完整性及切除量,单独确定颈椎间盘置换的活动范围。
全膝关节置换有两种基本类型,保留后交叉韧带和牺牲后交叉韧带的设计。在颈椎中,根据手术过程中作为脊髓减压一部分是否需要完全切除后纵韧带,在生物力学上存在类似情况——在概念上区分保留后纵韧带和牺牲后纵韧带的全颈椎间盘置换可能会有所帮助。
