ESTRO 2023 - Abstract Book

S2083

Digital Posters

ESTRO 2023

Conclusion This online integrated system solved the bottleneck in our previous clinical workflow. With this system, we not only improved the RT treatment process, but also saved much time for our working staff, reduced clinical error and improved patient safety.

PO-2314 Development of an anthropomorphic 4D Phantom for multimodal imaging, 4D radiation and SGRT

A. Bakhtiari Moghaddam 1

1 german cancer research center (dkfz), Medical Physics in Radiation Oncology, Heidelberg, Germany

Purpose or Objective

inevitable patient movements during imaging can result in interfractional and intrafractional errors, originating mainly from the respiratory motions during the radiation planning, namely dosimetry planning. These errors might also arise from issues in patient positioning or be due to imaging artifacts. Advancements in four-dimensional (4D) radiotherapy and the development of adaptive radiotherapy that examines patient motion during imaging and radiotherapy can facilitate the recognition and reduction of such errors. Use of Surface Guided Radiation Therapy (SGRT) makes it possible to get even closer to this goal. Using an anthropomorphic 4D phantom, the quality of radiation can be verified from start to the end. Materials and Methods The phantom includes the following organ model: lungs, liver, kidneys, spleen, duodenum, stomach, pancreas, parts of the large and small intestine and bones of the spine.The required organs and bones were segmented using CT scan data of a patient and three-dimensional models were created. using CAD software, the mold for the organ and bone models can be designed. The models are produced using the 3D printer. After fabricating the molds, depending on the requirements of the model, they were filled with either a prepared liquid contrast gel NiDTPA-KCl agarose mixture, a liquid contrast, or silicone. Three tumor models were applied in the liver model, each of which was loaded with EBT3 measurement films. The phantom body was made in a form of a mannequin from transparent acrylonitrile butadiene styrene (ABS). The fabricated models were placed in a matrix of superabsorbent and agarose gel. Using a hydraulic system, the lung models were designed to be filled with air and the lower abdominal membrane can be pressed mechanically. The pressure generated by the diaphragm model in the abdominal region and the lower abdominal membrane pressed by an actuator make it possible to simulate a respiratory movement in the abdominal cavity. It also causes a movement in the abdominal wall model.