ESTRO 2022 - Abstract Book

S45

Abstract book

ESTRO 2022

PD-0070 A data mining-based approach to predict the growth of brain structures after pediatric radiotherapy

R.G. Raidou 1 , L.P. Muren 2 , L.V. Toussaint 3 , D. Indelicato 4 , C. Magg 1

1 TU Wien, Institute of Visual Computing & Human-Centered Technology, Vienna, Austria; 2 Danish Centre for Particle Therapy, Department of Medical Physics, Aarhus, Denmark; 3 Danish Centre for Particle Therapy, Department of Medical Physics, Department of Medical Physics, Aarhus, Denmark; 4 University of Florida, Department of Radiation Oncology, Gainesville, FL, USA Purpose or Objective Radiotherapy (RT) to children with brain tumors influences the growth and cognitive development of nearby structures. Studies relating longitudinal brain changes to the doses delivered to critical structures require re-segmentation. The aim of this study was to develop a data mining-based method to predict the growth of structures in pediatric brain tumor patients treated with RT. Materials and Methods Co-registered Computed Tomography (CT) pre-treatment scans and 1-3 post-treatment Magnetic Resonance (MR) scans from 20 patients with brain tumors treated with RT were used. A total of 21 brain structures were selected based on potential association to cognitive function. Our approach consisted of three steps (Fig.1): (i) predicting segmentations of structures post-treatment based on pre-treatment data; (ii) quantifying the prediction accuracy; and (iii) visualizing structure evolution and its accuracy. In the first step, pre-treatment masks were used to predict post-treatment masks on MR images. For this, an active contour model was initialized with a dilated version of the pre-treatment masks. The parameters of the contour model and the selected dilation kernel might influence the prediction, and thus a two-step hyperparameter search was used to determine their optimal values by quantifying the divergence from ground truth. In the second step, a support vector regressor (SVR) with 35 features (related to geometry, intensity, and gradients) was trained on the pre-treatment data and ground truth information (Fig.2). The accuracy of post-treatment predictions was quantified using the Jaccard index (taking values from 0 to 1, with 1 indicating complete similarity). In the third step, a distance transform operation was employed to calculate the distances between pre-and post-treatment data. This was used to visualize the predicted growth of a structure and its respective accuracy.

Fig.1: The proposed approach.

Fig.2: SVR Training.

Results Three parameters (dilation kernel size, smoothness, and maximal number of iterations) influenced the outcome of the segmentation the most. Segmentations of larger structures were more accurately predicted, but overall the prediction accuracy behavior was learned correctly for all structures. The Jaccard index was higher for large structures, such as the brain (0.81) and temporal lobe (0.74), as compared to smaller structures, such as the thalamus anterior (0.09) and hypothalamus (0.11). The support vector regression predicted the Jaccard distance with a mean squared error between 0.03-0.08, i.e., the behavior observed in the training dataset was learned correctly. The visualization showed the predicted growth patterns and their accuracy.

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