Department of Orthopaedic Surgery, NYU Langone Medical Center's Hospital for Joint Diseases, 301 East 17th St, New York, NY 10003, USA.
Spine J. 2013 Apr;13(4):375-81. doi: 10.1016/j.spinee.2012.05.029. Epub 2012 Aug 15.
Thoracic pedicle screw (TPS) constructs have improved curve correction measurements compared with hook and hybrid constructs in the treatment of adolescent idiopathic scoliosis (AIS), but the optimal implant density, or the number of screws per level, remains unknown in the treatment of flexible thoracic curves.
To determine how implant density affects clinical outcome, radiographic outcome, and cost in the treatment of Lenke Curve Type I AIS.
A retrospective clinical study.
Ninety-one consecutive AIS patients with Lenke Type I curves who underwent surgical correction with a minimum follow-up of 24 months.
Radiographic outcomes included assessment of preoperative and 2-year postoperative thoracic Cobb angle, T5-T12 kyphosis, and curve flexibility. We also assessed SRS-22 outcome measures and thoracic angle of trunk rotation (ATR) before surgery and at the 2-year postoperative time point. The cost of each construct was also evaluated.
Bivariate analysis was conducted between implant density and the following factors: percent correction of the major curve, ATR, and change in kyphosis. The correlation between curve flexibility and percent correction of the major curve was determined. Patients were then divided into two groups: the low-density (LD) TPS group defined by implant density below the mean number of screws per level for the entire cohort (less than 1.3 screws per level) and the high-density (HD) TPS group defined by implant density above the mean number of screws per level (more than 1.3 screws per level). Independent sample t tests were used to compare demographic data as well as radiographic and clinical outcomes at baseline and at follow-up between the two groups.
Sixty-one female and 30 male patients met inclusion criteria. No significant correlations were found between implant density and the following parameters: percent correction of the major curve (p=.25), ATR (p=.75), and change in T5-T12 kyphosis (p=.40). No correlation was found between curve flexibility and percent correction of the major curve (p=.54). The LD group consisted of 57 patients, whereas the HD group had 34 patients. There were no differences between the HD group and the LD group in regard to major curve correction, change in T5-T12 kyphosis, or change in ATR. Total implant costs were significantly higher in the HD group ($13,272 vs. $10,819; p<.01). The SRS-22 image domain and overall score improved at 2 years within both groups, but there were no group differences in any of the SRS-22 domains or the overall score.
We identified no clinical, radiographic, perioperative, or complication-related advantage of constructs with higher TPS implant density in this patient cohort with flexible idiopathic scoliosis. Cost was significantly higher with HD constructs in comparison with LD constructs. Optimal implant density chosen by the surgeon should rely on a number of factors including curve magnitude and rigidity, bone density, and desired correction.
与钩和混合结构相比,胸椎椎弓根螺钉(TPS)结构在治疗青少年特发性脊柱侧凸(AIS)方面改善了曲线矫正测量值,但在治疗柔韧的胸椎曲度时,最佳植入物密度(即每个节段的螺钉数量)仍不清楚。
确定植入物密度如何影响治疗 Lenke 曲线 I 型 AIS 的临床结果、影像学结果和成本。
回顾性临床研究。
91 例连续 AIS 患者,Lenke 型 I 型曲线,接受至少 24 个月的手术矫正。
影像学结果包括术前和 2 年术后的胸椎 Cobb 角、T5-T12 后凸和曲线柔韧性的评估。我们还评估了 SRS-22 结果测量值和术前和 2 年术后时间点的躯干旋转胸椎角(ATR)。还评估了每个结构的成本。
在植入物密度与主要曲线矫正百分比、ATR 和曲线柔韧性之间进行双变量分析。确定曲线柔韧性与主要曲线矫正百分比之间的相关性。然后将患者分为两组:低密度(LD)TPS 组定义为植入物密度低于整个队列的每个节段平均螺钉数(低于 1.3 个螺钉/节段),高密度(HD)TPS 组定义为植入物密度高于每个节段的平均螺钉数(大于 1.3 个螺钉/节段)。使用独立样本 t 检验比较两组之间基线和随访时的人口统计学数据以及影像学和临床结果。
我们发现植入物密度与以下参数之间没有显著相关性:主要曲线矫正百分比(p=.25)、ATR(p=.75)和 T5-T12 后凸变化(p=.40)。曲线柔韧性与主要曲线矫正百分比之间也没有相关性(p=.54)。LD 组有 57 例患者,HD 组有 34 例患者。在主要曲线矫正、T5-T12 后凸变化或 ATR 变化方面,HD 组与 LD 组之间没有差异。HD 组的总植入物成本明显高于 LD 组($13,272 与 $10,819;p<.01)。两组的 SRS-22 图像域和总体评分在 2 年内均有所改善,但在 SRS-22 任何一个域或总体评分方面均无组间差异。
我们没有发现这种具有柔韧特发性脊柱侧凸的患者队列中,高 TPS 植入物密度的结构在临床、影像学、围手术期或并发症方面具有优势。与 LD 结构相比,HD 结构的成本明显更高。外科医生选择的最佳植入物密度应取决于多个因素,包括曲线幅度和刚性、骨密度和预期矫正。
