Departments of Neurological Surgery and.
J Neurosurg Spine. 2014 Apr;20(4):364-70. doi: 10.3171/2013.12.SPINE13386. Epub 2014 Jan 24.
Reconstruction after total sacrectomy is a critical component of malignant sacral tumor resection, permitting early mobilization and maintenance of spinal pelvic alignment. However, implant loosening, graft migration, and instrumentation breakage remain major problems. Traditional techniques have used interiliac femoral allograft, but more modern methods have used fibular or cage struts from the ilium to the L-5 endplate or sacral body replacement with transiliac bars anchored to cages to the L-5 endplate. This study compares the biomechanical stability under gait-simulating fatigue loading of the 3 current methods.
Total sacrectomy was performed and reconstruction was completed using 3 different constructs in conjunction with posterior spinal screw rod instrumentation from L-3 to pelvis: interiliac femur strut allograft (FSA); L5-iliac cage struts (CSs); and S-1 body replacement expandable cage (EC). Intact lumbar specimens (L3-sacrum) were tested for flexion-extension range of motion (FE-ROM), axial rotation ROM (AX-ROM), and lateral bending ROM (LB-ROM). Each instrumented specimen was compared with its matched intact specimen to generate an ROM ratio. Fatigue testing in compression and flexion was performed using a custom-designed long fusion gait model.
Compared with intact specimen, the FSA FE-ROM ratio was 1.22 ± 0.60, the CS FE-ROM ratio was significantly lower (0.37 ± 0.12, p < 0.001), and EC was lower still (0.29 ± 0.14, p < 0.001; values are expressed as the mean ± SD). The difference between CS and EC in FE-ROM ratio was not significant (p = 0.83). There were no differences in AX-ROM or LB-ROM ratios (p = 0.77 and 0.44, respectively). No failures were noted on fatigue testing of any EC construct (250,000 cycles). This was significantly improved compared with FSA (856 cycles, p < 0.001) and CS (794 cycles, p < 0.001).
The CS and EC appear to be significantly more stable constructs compared with FSA with FE-ROM. The 3 constructs appear to be equal with AX-ROM and LB-ROM. Most importantly, EC appears to be significantly more resistant to fatigue compared with FSA and CS. Reconstruction of the load transfer mechanism to the pelvis via the L-5 endplate appears to be important in maintenance of alignment after total sacrectomy reconstruction.
全骶骨切除术的重建是恶性骶骨肿瘤切除的关键组成部分,可实现早期活动和维持脊柱骨盆对线。然而,植入物松动、移植物迁移和器械断裂仍然是主要问题。传统技术使用髂骨股骨同种异体移植物,但更现代的方法是使用从髂骨到 L-5 终板的腓骨或笼状支柱,或使用跨髂骨杆固定到笼状物的骶骨体置换。本研究比较了在步态模拟疲劳加载下 3 种当前方法的生物力学稳定性。
进行全骶骨切除术,并使用 3 种不同的结构完成重建,同时结合从 L-3 到骨盆的后路脊柱螺钉棒器械:髂骨股骨支柱同种异体移植物(FSA);L5-髂骨笼状支柱(CSs);和 S-1 体置换可扩张笼(EC)。对完整的腰椎标本(L3-骶骨)进行屈伸范围运动(FE-ROM)、轴向旋转 ROM(AX-ROM)和侧向弯曲 ROM(LB-ROM)测试。将每个器械化标本与匹配的完整标本进行比较,以生成 ROM 比。使用定制的长融合步态模型在压缩和弯曲下进行疲劳测试。
与完整标本相比,FSA 的 FE-ROM 比为 1.22±0.60,CS 的 FE-ROM 比显著降低(0.37±0.12,p<0.001),EC 的比仍然更低(0.29±0.14,p<0.001;值表示为平均值±标准差)。CS 和 EC 在 FE-ROM 比之间的差异无统计学意义(p=0.83)。AX-ROM 和 LB-ROM 比无差异(p=0.77 和 0.44)。在任何 EC 结构的疲劳测试中均未出现失效(250,000 次循环)。这与 FSA(856 次循环,p<0.001)和 CS(794 次循环,p<0.001)相比有显著改善。
CS 和 EC 与 FSA 相比,FE-ROM 的稳定性明显更高。这 3 种结构在 AX-ROM 和 LB-ROM 方面似乎是相等的。最重要的是,EC 似乎比 FSA 和 CS 更能抵抗疲劳。通过 L-5 终板向骨盆传递负荷的机制重建似乎对全骶骨切除重建后的对线维持很重要。
