SU‐C‐BRA‐01: Interactive Auto‐Segmentation for Bowel in Online Adaptive MRI‐Guided Radiation Therapy by Using a Multi‐Region Labeling Algorithm

Abstract

Purpose:In MRI‐guided online adaptive radiation therapy, re‐contouring of bowel is time‐consuming and can impact the overall time of patients on table. The study aims to auto‐segment bowel on volumetric MR images by using an interactive multi‐region labeling algorithm.Methods:5 Patients with locally advanced pancreatic cancer underwent fractionated radiotherapy (18–25 fractions each, total 118 fractions) on an MRI‐guided radiation therapy system with a 0.35 Tesla magnet and three Co‐60 sources. At each fraction, a volumetric MR image of the patient was acquired when the patient was in the treatment position. An interactive two‐dimensional multi‐region labeling technique based on graph cut solver was applied on several typical MRI images to segment the large bowel and small bowel, followed by a shape based contour interpolation for generating entire bowel contours along all image slices. The resulted contours were compared with the physician's manual contouring by using metrics of Dice coefficient and Hausdorff distance.Results:Image data sets from the first 5 fractions of each patient were selected (total of 25 image data sets) for the segmentation test. The algorithm segmented the large and small bowel effectively and efficiently. All bowel segments were successfully identified, auto‐contoured and matched with manual contours. The time cost by the algorithm for each image slice was within 30 seconds. For large bowel, the calculated Dice coefficients and Hausdorff distances (mean±std) were 0.77±0.07 and 13.13±5.01mm, respectively; for small bowel, the corresponding metrics were 0.73±0.08and 14.15±4.72mm, respectively.Conclusion:The preliminary results demonstrated the potential of the proposed algorithm in auto‐segmenting large and small bowel on low field MRI images in MRI‐guided adaptive radiation therapy. Further work will be focused on improving its segmentation accuracy and lessening human interaction.