Harris Basil M, Hilibrand Alan S, Savas Paul E, Pellegrino Anthony, Vaccaro Alexander R, Siegler Sorin, Albert Todd J
Biomechanics Laboratory of Drexel University, Philadelphia, Pennsylvania, USA.
Spine (Phila Pa 1976). 2004 Feb 15;29(4):E65-70. doi: 10.1097/01.brs.0000113034.74567.86.
In vitro comparison of four reconstruction techniques following transforaminal lumbar interbody fusion in a human cadaveric model.
Transforaminal lumbar interbody fusion (TLIF) is a relatively new technique that avoids the morbidity of an anterior approach and the nerve root manipulation of a posterior interbody fusion. This study measured the effects of a TLIF on the overall and segmental flexibility of the lumbar spine using four different spinal implant configurations.
Anterior lumbar interbody fusion, posterior lumbar interbody fusion, and combined anterior-posterior spinal procedures are gaining wide acceptance for the treatment of selected patients with segmental spinal instability and spondylolisthesis with associated degenerative changes. Each fusion technique may have different effects on the overall flexibility of the lumbar spine. The unilateral TLIF procedure with adjunctive pedicular fixation is one variation of an interbody fusion technique that requires less bony and soft tissue dissection and minimizes nerve root manipulation compared with other interbody fusion methods.
Five fresh-frozen, human lumbar spines were nondestructively subjected to flexion, extension, lateral bending, and axial rotation moments using a previously validated spine flexibility tester, and displacements were measured. Testing the intact lumbar spine was followed by testing of a unilateral L4-L5 TLIF using a single ramp carbon fiber cage without adjunctive internal fixation. The single carbon fiber (Brantigan) cage was inserted obliquely in a posterolateral to anteromedial position in the L4-L5 disc space. Following testing of the cage alone, three different adjunctive stabilization techniques were tested. Posterior stabilization involved one of the following: a contralateral translaminar facet screw, single side/ipsilateral nonsegmental pedicle screw fixation, and bilateral nonsegmental pedicle screw fixation. The overall flexibility of each lumbar spine was calculated from load-displacement curves for each axis of rotation. The flexibility of the L4-L5 segment of each spine was computed from kinematic motion data acquired via attached LED sensors to the L4 and L5 vertebral bodies. Statistical testing was performed with paired t tests.
The flexibility of the entire (T12-S1) destabilized spine after TLIF with interbody cage alone and with all three reconstructive techniques was comparable with the intact spine. However, the motion at the L4-L5 segment was significantly increased for the TLIF with interbody cage alone in axial rotation (299% of intact, P < 0.01), with no significant change in flexion-extension (79% of intact, P = 0.22) or lateral bending (87% of intact, P = 0.39). With the addition of a contralateral translaminar facet screw, the motion at the L4-L5 segment remained significantly more flexible in axial rotation (250% of intact, P = 0.06) although less than with the cage alone. With the unilateral pedicle screw construct, the L4-L5 segment remained more flexible in axial rotation (182% of intact, P = 0.07) although significantly less than with the facet screw construct (P < 0.05). The addition of bilateral pedicle screws most closely reapproximated the flexibility of the intact spine with no significant difference in axial rotation (91% of intact, P = 0.30), flexion-extension (93% of intact, P = 0.19), or lateral bending (99% of intact, P = 0.47). The motion at the L4-L5 segment with bilateral pedicle screws was not significantly different than for the intact specimen in axial rotation (144% of intact, P = 0.17), flexion-extension (81% of intact, P = 0.21), or lateral bending (86% of intact, P = 0.27).
TLIF reconstruction with a solitary cage did not increase overall spine flexibility from the intact condition but significantly increased segmental flexibility at L4-L5 in axial rotation. A unilateral translaminar facet screw had minimal stabilizing effect at L4-L5. Unilateral pedicle screws frews further increased stiffness at the L4-L5 segment. However, TLIF with bilateral pedicle screws most closely approximated the L4-L5 segmental flexibility of the intact spine.
在人体尸体模型中对经椎间孔腰椎椎间融合术后四种重建技术进行体外比较。
经椎间孔腰椎椎间融合术(TLIF)是一种相对较新的技术,可避免前路手术的并发症以及后路椎间融合术中对神经根的操作。本研究使用四种不同的脊柱植入物配置测量了TLIF对腰椎整体和节段灵活性的影响。
前路腰椎椎间融合术、后路腰椎椎间融合术以及前后联合脊柱手术在治疗选定的伴有节段性脊柱不稳和椎体滑脱及相关退变改变的患者中得到广泛认可。每种融合技术对腰椎的整体灵活性可能有不同影响。与其他椎间融合方法相比,单侧TLIF联合椎弓根固定术是一种椎间融合技术的变体,需要较少的骨和软组织剥离,并将神经根操作降至最低。
使用先前验证过的脊柱灵活性测试仪对五个新鲜冷冻的人体腰椎进行无损的前屈、后伸、侧屈和轴向旋转力矩测试,并测量位移。在测试完整腰椎后,使用单个斜面碳纤维椎间融合器进行单侧L4-L5 TLIF测试,不进行辅助内固定。将单个碳纤维(Brantigan)椎间融合器斜向插入L4-L5椎间盘间隙的后外侧至前内侧位置。在单独测试椎间融合器后,测试三种不同的辅助稳定技术。后路稳定包括以下之一:对侧经椎板小关节螺钉、单侧/同侧非节段性椎弓根螺钉固定和双侧非节段性椎弓根螺钉固定。根据每个旋转轴的载荷-位移曲线计算每个腰椎的整体灵活性。根据通过连接到L4和L5椎体的LED传感器获取的运动学数据计算每个脊柱L4-L5节段的灵活性。使用配对t检验进行统计学测试。
单独使用椎间融合器以及所有三种重建技术进行TLIF后,整个(T12-S1)失稳脊柱的灵活性与完整脊柱相当。然而,单独使用椎间融合器进行TLIF时,L4-L5节段在轴向旋转时的运动显著增加(为完整状态的299%,P<0.01),在前屈-后伸(为完整状态的79%,P = 0.22)或侧屈(为完整状态的87%,P = 0.39)时无显著变化。添加对侧经椎板小关节螺钉后,L4-L5节段在轴向旋转时的运动仍然明显更灵活(为完整状态的250%,P = 0.06),尽管比单独使用椎间融合器时小。使用单侧椎弓根螺钉结构时,L4-L5节段在轴向旋转时仍然更灵活(为完整状态的182%,P = 0.07),尽管明显小于使用小关节螺钉结构时(P<0.05)。添加双侧椎弓根螺钉最接近完整脊柱的灵活性,但在轴向旋转(为完整状态的91%,P = 0.30)、前屈-后伸(为完整状态的93%,P = 0.19)或侧屈(为完整状态99%,P = 0.47)方面无显著差异。双侧椎弓根螺钉固定时L4-L5节段在轴向旋转(为完整状态的144%,P = 0.17)、前屈-后伸(为完整状态的81%,P = 0.21)或侧屈(为完整状态的86%,P = 0.27)方面与完整标本无显著差异。
单独使用椎间融合器进行TLIF重建并未使整个脊柱的灵活性从完整状态增加,但显著增加了L4-L5节段在轴向旋转时的节段灵活性。单侧经椎板小关节螺钉在L4-L5处的稳定作用最小。单侧椎弓根螺钉进一步增加了L4-L5节段的刚度。然而,双侧椎弓根螺钉固定的TLIF最接近完整脊柱的L4-L5节段灵活性。
