Contrast-Free Virtual Enhancement: A Deep Learning Solution for Radiotherapy Target Delineation In Patients with Contrast Contraindications
Abstract
Purpose
Contrast-enhanced CT (CECT) is routinely used in radiotherapy planning to improve visualization of tumors, lymph nodes, and vascular anatomy for accurate target delineation. However, contrast administration is contraindicated in a subset of patients (e.g., iodine allergy, renal insufficiency), and reliance on non-contrast planning CT (pCT) alone may compromise soft-tissue contrast and introduce contouring uncertainty. We propose a Multi-Modal Generative Synthesis Network (MMGSN) to generate synthetic CECT (sCECT) from pCT and T2-weighted MRI, aiming to provide a non-invasive “virtual enhancement” tool for contouring support without physical contrast injection.
Methods
We retrospectively collected 47 pelvic tumor patients treated with radiotherapy, each with paired non-contrast pCT, T2-weighted MRI, and ground-truth CECT. For each patient, the CECT volume used in this study consisted of 40 axial slices (used as the reference for training/evaluation). MMGSN adopts a dual-stream encoder to fuse the geometric fidelity of pCT with the soft-tissue characterization of MRI, followed by a decoder to reconstruct high-fidelity sCECT. Training employed a compound objective combining adversarial loss, weighted L1 loss, and SSIM loss. Performance was evaluated on a held-out test set using PSNR, SSIM, and MSE, and compared against the baseline similarity between pCT and CECT.
Results
MMGSN generated sCECT with high quantitative fidelity to ground-truth CECT, achieving a mean PSNR of 43.36 dB and mean SSIM of 0.979 on the test set. Compared with the baseline (pCT vs CECT), MMGSN demonstrated a clear improvement in perceptual/structural similarity (e.g., representative case: SSIM 0.978 vs 0.966 and PSNR 43.088 vs 39.757, respectively). As illustrated in the tri-planar views (axial/coronal/sagittal), sCECT better reproduced contrast-related appearance and improved delineation cues for pelvic vasculature and soft-tissue boundaries relative to pCT, while maintaining geometric consistency required for radiotherapy planning.
Conclusion
MMGSN enables high-quality generation of contrast-free sCECT from pCT and MRI in pelvic radiotherapy patients.