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Deep learning analysis of MRI to assess rectal cancer treatment.

Deep learning analysis of MRI to assess rectal cancer treatment. Frontiers in oncology Selby, H. M., Son, A. Y., Sheth, V. R., Wagner, T. H., Pollom, E. L., Morris, A. M. 2025; 15: 1643852

Abstract

Traditional neoadjuvant therapy for locally advanced rectal cancer (LARC) results in pathologic complete response (pCR) in approximately 15% of patients, supporting non-operative strategies for those with clinical complete response (cCR). The subjectivity and variability in MRI-based cCR assessments highlight the need for objective, quantitative tools.To develop deep learning models for automated rectal tumor segmentation on pre- and post-treatment MRIs, and to identify radiomic features differentiating cCR from non-cCR patients.We retrospectively analyzed pre- and post-treatment MRIs from 37 LARC patients enrolled in a Phase 2 TNT trial (NCT04380337). Rectal tumors were segmented on T2-weighted images by two data scientists, refined by a radiologist (reference standard), and independently segmented by a fellow. For pre-treatment segmentation, Model 1 (baseline; n = 37 ) was trained on reference cases, then used to generate pseudo-labels for 81 additional cases. Model 2 (semi-supervised; n = 118 ) was trained on the combined dataset. Model 3 (baseline; n = 37 ) was trained on post-treatment cases. Radiomic features were extracted from post-treatment ADC maps, filtered by reproducibility (ICC = 0.8 ) and redundancy (Spearman ? = 0.95 ), then analyzed using unsupervised hierarchical clustering.For pre-treatment segmentation, radiologist-fellow inter-rater agreement was DSC = 0.748 ± 0.092 . Model 1 achieved mean DSC = 0.682 ± 0.254 versus the radiologist, significantly lower than inter-rater agreement. Model 2 improved performance to mean DSC = 0.769 ± 0.214 (mean gain = 0.087 ; 12.8 % relative improvement; p < 0.001 ), slightly outperforming inter-rater agreement. For post-treatment segmentation, inter-rater agreement declined to mean DSC = 0.362 ± 0.256 , while Model 3 achieved mean DSC = 0.175 ± 0.231 versus the radiologist, reflecting challenges from treatment-induced tissue changes affecting both automated models and human raters. Radiomic clustering revealed two distinct patient groups aligned with cCR and non-cCR status.This study demonstrates the feasibility of deep learning-based automated segmentation and radiomic profiling for differentiating treatment response in rectal cancer. Semi-supervised learning with pseudo-labeled data significantly improved segmentation performance, offering a practical approach to overcome limited annotations. Radiomic features warrant validation in larger multi-center studies for clinical translation.

View details for DOI 10.3389/fonc.2025.1643852

View details for PubMedID 41737732

View details for PubMedCentralID PMC12927481