ESTRO 2023 - Abstract Book

S558

Sunday 14 May 2023

ESTRO 2023

Two cycleGANs were trained independently on two datasets consisting of 70 pelvic CBCT and planning CT (pCT) pairs. The 'clean' model was machine-specific; trained on 70 CBCT/pCT pairs from a single treatment machine, under consistent calibration settings, while the 'messy' model was trained on 70 CBCT/pCT pairs collected from five treatment machines in a single centre, with no attention paid to calibration dates. For evaluation, the sCTs were compared against a corresponding deformed CT (dCT): the pCT deformably registered to the CBCT using ADMIRE v3.43.0 (Elekta AB). Both models were tested on two test datasets each consisting of an additional 25 CBCT/pCT pairs. The 'clean' test set was collected from the single treatment machine, and the 'messy' test set was from the five machines. Global image similarity metrics; mean absolute error (MAE), root mean squared error (RMSE), structural similarity index (SSIM) and normalised cross-correlation (NCC), were calculated between sCTs and dCT within the body contour. A Wilcoxon signed-rank test was used to identify differences between the metrics. Results Results indicate that image synthesis models trained with multi-machine data outperform single-machine models on all test sets in terms of image similarity, shown by reduced MAE and RMSE, and increased SSIM (Figure 2A). Differences in CBCT machine and calibration within training data do not appear to hinder sCT image quality, instead offering increased generalisability. However, there is no significant difference between model performance (p ≥ 0.068) as shown in Figure 2B i)-iv). This suggests that although initial results indicate that diverse training data improves sCT quality, dosimetric analysis is needed to indicate if this is significant.

Conclusion Initial results of image synthesis models trained on varied, multi-machine data outperform models trained on single machine data. As an additional benefit, an sCT generation model, generalised to multiple machines, would be more easily deployed in the clinic. These results should be externally validated, and the effects on the clinical workflow e.g., dosimetric impact and contour propagation investigated. PD-0666 Dose reduction for respiratory signal-guided step-and-shoot 4DCT by online dose modulation R. Werner 1 , A. Schwarz 2 , L. Wimmert 1 , L. Büttgen 3 , M. Vornehm 2 , T. Gauer 4 , C. Hofmann 2 1 University Medical Center Hamburg-Eppendorf, Department of Computational Neuroscience, Hamburg, Germany; 2 Siemens Healthcare, --, Forchheim, Germany; 3 University Medical Center Hamburg-Eppendorf, Department of Radiotherapy and Radio-Oncology, Hamburg, Germany; 4 University Medical Center Hamburg-Eppendorf, Department of Radiotherapy and Radiation Oncology, Hamburg, Germany Purpose or Objective Respiratory signal-guided 4DCT scanning reduces image artifacts compared to conventional 4CT approaches, especially for irregular breathing. Intelligent 4DCT sequence scanning (i4DCT) is a corresponding step-and-shoot scan protocol that selects beam-on/off periods online such that the data sufficiency condition (DSC) is fulfilled at each couch position. In case of long