Poster 251: Tibial Tuberosity to Trochlear Groove Distance (TT-TG): A Patellar Instability Gold Standard Prone to Errors?

Objectives: For decades, tibial tuberosity–trochlear groove (TT-TG) distance has been the gold standard for clinical decision-making in patellar instability. Therefore, the accuracy of the metric has large implications for patient care. Numerous studies and reviews have pointed out potential sources of measurement error in TT-TG, such as differences in landmark selection, flexion of the knee while measuring, and axial alignment of the knee in the scanner. Most studies have reported high interrater reliability (IRR) for landmark selection to justify using TT-TG as a clinical metric without detailing errors within the scan. These errors, such as axial alignment of the knee, occur because TT-TG simplifies a 3-dimensional (3D) feature using a 2-dimensional (2D) measurement. To date, no studies have analyzed how these simplification errors translate into clinical practice. The objective of this study is to develop a 3D method to quantify the discrepancy between classic TT-TG measured in 2D (2D TT-TG) and the true TT-TG measured in 3D (3D TT-TG). In addition, we quantify the change in measured TT-TG depending on whether the most proximal, the most distal, or an intermediate point in the trochlear groove is chosen. Methods: High resolution computed tomography (CT) scans of 20 patients with lateral patellofemoral instability and of 20 control knees from the New Mexico Decedent Image Database were segmented, and 3D models created. The femoral posterior condyles, proximal, middle, and distal trochlear groove, tibial shaft center, and tibial intercondylar tubercles were marked on each model. These landmarks are the basis for a 3D TT-TG measurement analogous to TT-TG measured on axial CT slices. 3D TT-TG distance was measured perpendicular to the longitudinal tibial axis (chosen to minimize the influence of Q-angle and, therefore, sex) and the corresponding posterior femoral condyle line for all 3D models. 2D TT-TG was measured perpendicular to the posterior condyle line on axial slices, using the same landmarks as true TT-TG. In addition, the coronal angle between the tibia longitudinal axis and the corresponding axis of the scanner was calculated. TT-TG measurements were carried out for the most proximal and most distal points as well as the midpoint of the trochlear groove. Significant differences between patients and controls were analyzed with a Mann-Whitney U test. P values 5 mm – more than the mean difference between the patient and control groups. Differences between 2D and 3D TT-TG were significantly correlated with scanner-tibia alignment. Knees that were correctly positioned within the scanner showed minimal differences between 2D and 3D TT-TG, showing that the current method of measuring TT-TG can be used in clinical practice if a robust radiological protocol is in place to ensure proper tibial axis alignment. However, due to the significant difference between 2D and 3D TT-TG population values and the inconsistent thresholds defined in studies without exclusion criteria for patient knee alignment, the use of TT-TG must be reevaluated. Variation of the proximity of the point within the trochlea can cause differences in TT-TG of >10 mm. Universal agreement on where to measure is necessary to achieve a standard in clinical decision-making; choosing a distal point reduces error and variation overall. Due to current limitations of the sample, we cannot yet estimate error prevalence. This study shows that the radiological metric TT-TG, the cornerstone of clinical decision-making in patellar instability, is susceptible to errors caused by patient-scanner alignment. Robust radiological protocols can be used to minimize this error.