A Systematic Post-Processing Approach for Quantitative T1 Imaging of Knee Articular Cartilage

Abstract

Objective: To establish an automated pipeline for post-processing of quantitative spin-lattice relaxation time constant in the rotating frame (T1) imaging of knee articular cartilage. Design: The proposed post-processing pipeline commences with an image standardisation procedure, followed by deep learning-based segmentation to generate cartilage masks. The articular cartilage is then automatically parcellated into 20 subregions, where T1 quantification is performed. The proposed pipeline was retrospectively validated on a dataset comprising knee T1 images of 10 healthy volunteers and 30 patients with knee osteoarthritis. Three experiments were conducted, namely an assessment of segmentation model performance (using Dice similarity coefficients, DSCs); an evaluation of the impact of standardisation; and a test of T1 quantification accuracy (using paired t-tests; root-mean-square deviations, RMSDs; and coefficients of variance of RMSDs, CVRMSD). Statistical significance was set as p<0.05. Results: There was a substantial agreement between the subregional T1 quantification from the model-predicted masks and those from the manual segmentation labels. In patients, 17 of 20 subregions, and in healthy volunteers, 18 out of 20 subregions, demonstrated no significant difference between predicted and reference T1 quantifications. Average RMSDs were 0.79 ms for patients and 0.56 ms for healthy volunteers, while average CVRMSD were 1.97% and 1.38% for patients and healthy volunteers. Bland-Altman plots showed negligible bias across all subregions for patients and healthy volunteers. Conclusion: The proposed pipeline can perform automatic and reliable post-processing of quantitative T1 images of knee articular cartilage.