Strategies for Motion Robust Proton Therapy With Pencil Beam Scanning for Esophageal Cancer

Strategies for Motion Robust Proton Therapy With Pencil Beam Scanning for Esophageal Cancer

Proton therapy of esophageal cancer is superior to photon radiation therapy in terms of normal tissue sparing. However, respiratory motion and anatomical changes may compromise target dose coverage owing to density changes, geometric misses, and interplay effects. Here we investigate the combined ef...

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Published in:International journal of radiation oncology, biology, physics Vol. 111; no. 2; pp. 539 - 548
Main Authors: Møller, Ditte Sloth, Poulsen, Per Rugaard, Hagner, Andreas, Dufour, Mathieu, Nordsmark, Marianne, Nyeng, Tine Bisballe, Mortensen, Hanna Rahbek, Lutz, Christina Maria, Hoffmann, Lone
Format: Journal Article
Language:English
Published: United States Elsevier Inc 01-10-2021
Subjects:
ANIMAL TISSUES
ESOPHAGUS
NEOPLASMS
PROTON BEAMS
RADIATION DOSES
RADIOLOGY AND NUCLEAR MEDICINE
RADIOTHERAPY
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Summary:Proton therapy of esophageal cancer is superior to photon radiation therapy in terms of normal tissue sparing. However, respiratory motion and anatomical changes may compromise target dose coverage owing to density changes, geometric misses, and interplay effects. Here we investigate the combined effect on clinical target volume (CTV) coverage and compare proton therapy with intensity modulated radiation therapy (IMRT). This study includes 26 patients with esophageal cancer previously treated with IMRT planned on 4-dimensional computed tomography (4D-CT). For each patient, 7 proton pencil beam scanning (PBS) plans were created with different field configurations and optimization strategies. The effect of respiration was investigated by calculating the phase doses, 4D dose, and 4D dynamic dose (including interplay effects). The effect of anatomical changes was investigated by recalculating all plans on all phases of a 4D-CT surveillance scan. The most robust PBS plans were achieved using 2 posterior beams requiring coverage of planning target volume (PTV) and simultaneously using robust optimization (RO) of CTV (2PAPTVRO), resulting in only 1 patient showing V95%CTV <97% in 1 or more phases of the planning CT. For the least robust PBS plans obtained using lateral + posterior beams and CTV-RO, but not requiring PTV coverage (2LPRO), 10 patients showed underdosage. For IMRT, 2 patients showed underdosage. Interplay effects reduced V95%CTV significantly when delivering only 1 fraction, but the effects generally averaged out after 10 fractions. The effect of interplay was significantly larger for RO-only plans compared with plans optimized with RO combined with PTV coverage. Combining the effect of anatomical changes and respiration on the 4D-CT surveillance scan resulted in V95%CTV <97% for 3 2PAPTVRO, 16 2LPRO, and 8 IMRT patients. PBS using posterior beam angles was more robust to anatomical changes and respiration than IMRT. The effect of respiration was enhanced when anatomical changes were present. Single fraction interplay effects deteriorated the dose distribution but were averaged out after 10 fractions.
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ISSN:0360-3016
1879-355X
DOI:10.1016/j.ijrobp.2021.04.040