Analyzing Alignment Error in Tibial Tuberosity-Trochlear Groove Distance in Clinical Scans Using 2D and 3D Methods.

Johannes M Sieberer,Nancy Park,Albert L Rancu,Shelby T Desroches,Curtis McDonald,Armita R Manafzadeh,Steven M Tommasini,Daniel H Wiznia,John P Fulkerson
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Abstract

BACKGROUND Tibial tuberosity-trochlear groove distance (TT-TG) is often used as a primary metric for surgical decision-making in the treatment of patellofemoral instability (PFI), particularly when considering tibial tubercle transfer. Although TT-TG has high interrater reliability, it is prone to measurement differences caused by the alignment of the patient's leg in a scanner gantry, potentially influencing surgical decision-making. Quantification of this error within the clinical literature remains limited. PURPOSE To quantify and specify the error in TT-TG caused by leg-scanner alignment by using detailed topographical landmarks and 3-dimensional (3D) analysis of computed tomography scans of patients with PFI. STUDY DESIGN Controlled laboratory study. METHODS Three-dimensional models of knees with PFI were created from computed tomography scans and used to identify TT-TG landmarks. TT-TG was measured using the established 2-dimensional (2D) and 3D methods. A model to estimate the differences between these 2 methods was created, and the orientation of the patients' legs in relation to scanner longitudinal axis was measured to validate this model via linear regression. Interrater reliability was calculated via intraclass correlation coefficients (ICC). RESULTS A total of 44 knees of patients with PFI were analyzed. Differences between the 2D and 3D methods ranged from -4.0 to 14.7 mm (mean ± SD, 2.7 ± 4.1 mm) with a root mean square difference of 4.8 mm. The TT-TG distance of the 2D method (19.8 ± 7.2 mm) was significantly (P = .045) longer than that of the 3D method (17.1 ± 4.9 mm). The variance of the 2D method was significantly larger than that of the 3D method. In total, 13 (29.5%) of the knees had a difference of >5 mm between 2D and 3D TT-TG. The estimation model had an adjusted r2 value of 1.00 and a resulting root mean square difference of 0.21 mm. 3D TT-TGs interrater reliability was good to excellent (ICC, 0.94 [95 CI%, 0.81-0.98]). CONCLUSION 3D TT-TG can be used to correct scanner-leg alignment errors, some of which are substantial when using only 2D TT-TG measurements. CLINICAL RELEVANCE The findings in this study suggest a need for caution and awareness of the potential effects of differences in alignment of the axes of the leg and scanner when using purely 2D TT-TG as a basis for surgical planning.
使用二维和三维方法分析临床扫描中胫骨肘节-椎弓沟距离的对齐误差
背景胫骨结节-胫骨沟距离(TT-TG)经常被用作治疗髌骨股骨不稳(PFI)的手术决策的主要指标,尤其是在考虑胫骨结节转移时。虽然TT-TG具有很高的互测可靠性,但它很容易因患者腿部在扫描仪龙门架上的排列而产生测量差异,从而对手术决策产生潜在影响。目的通过使用详细的地形地标和对 PFI 患者的计算机断层扫描进行三维(3D)分析,量化和明确腿部扫描仪对齐造成的 TT-TG 误差。方法根据计算机断层扫描创建 PFI 膝关节的三维模型,并用于识别 TT-TG 地标。使用已确立的二维(2D)和三维方法测量 TT-TG。创建了一个模型来估算这两种方法之间的差异,并测量了患者腿部相对于扫描仪纵轴的方向,通过线性回归来验证该模型。通过类内相关系数(ICC)计算了相互间的可靠性。结果共分析了 44 名 PFI 患者的膝关节。二维和三维方法的差异范围为-4.0至14.7毫米(平均值±标准差,2.7±4.1毫米),均方根差异为4.8毫米。二维方法的 TT-TG 距离(19.8 ± 7.2 毫米)明显(P = 0.045)长于三维方法(17.1 ± 4.9 毫米)。二维方法的方差明显大于三维方法。共有 13 个膝关节(29.5%)的二维和三维 TT-TG 差异大于 5 毫米。估计模型的调整 r2 值为 1.00,得出的均方根差异为 0.21 毫米。结论三维 TT-TG 可用来纠正扫描仪与腿部的对齐误差,仅使用二维 TT-TG 测量时,有些误差很大。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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