PURPOSE: To assess carbon ion beam dose variation due to bowel gas movement in pancreatic radiotherapy. METHODS AND MATERIALS: Ten pancreatic cancer inpatients were subject to diagnostic contrast-enhanced dynamic helical CT examination under breath-holding conditions, which included multiple-phase dynamic CT with arterial, venous, and delayed phases. The arterial-venous phase and arterial-delayed phase intervals were 35 and 145 s, respectively. A compensating bolus was designed to cover the target obtained at the arterial phase. Carbon ion dose distribution was calculated by applying the bolus to the CT data sets at the other two phases. RESULTS: Dose conformation to the clinical target volume was degraded by beam overshoot/undershoot due to bowel gas movement. The D95 for clinical target volume was degraded from 98.2% (range, 98.0-99.1%) of the prescribed dose to 94.7% (range, 88.0-99.0%) at 145 s. Excessive dosing to normal tissues varied among tissues and was, for example, 12.2 GyE/13.1 GyE (0 s/145 s) for the cord and 38.8 GyE/39.8 GyE (0 s/145 s) for the duodenum. The magnitude of beam overshoot/undershoot was particularly exacerbated from the anterior and left directions. CONCLUSIONS: Bowel gas movement causes dosimetric variation to the target during treatment for radiotherapy. The effect of bowel gas movement varies with beam angle, with greatest influence on the anterior-posterior and left-right beams.
PURPOSE: To assess carbon ion beam dose variation due to bowel gas movement in pancreatic radiotherapy. METHODS AND MATERIALS: Ten pancreatic cancer inpatients were subject to diagnostic contrast-enhanced dynamic helical CT examination under breath-holding conditions, which included multiple-phase dynamic CT with arterial, venous, and delayed phases. The arterial-venous phase and arterial-delayed phase intervals were 35 and 145 s, respectively. A compensating bolus was designed to cover the target obtained at the arterial phase. Carbon ion dose distribution was calculated by applying the bolus to the CT data sets at the other two phases. RESULTS: Dose conformation to the clinical target volume was degraded by beam overshoot/undershoot due to bowel gas movement. The D95 for clinical target volume was degraded from 98.2% (range, 98.0-99.1%) of the prescribed dose to 94.7% (range, 88.0-99.0%) at 145 s. Excessive dosing to normal tissues varied among tissues and was, for example, 12.2 GyE/13.1 GyE (0 s/145 s) for the cord and 38.8 GyE/39.8 GyE (0 s/145 s) for the duodenum. The magnitude of beam overshoot/undershoot was particularly exacerbated from the anterior and left directions. CONCLUSIONS:Bowel gas movement causes dosimetric variation to the target during treatment for radiotherapy. The effect of bowel gas movement varies with beam angle, with greatest influence on the anterior-posterior and left-right beams.
Authors: Lianli Liu; Adam Johansson; Yue Cao; Rojano Kashani; Theodore S Lawrence; James M Balter Journal: Phys Med Biol Date: 2021-04-12 Impact factor: 3.609
Authors: Yuhang Zhang; Rojano Kashani; Yue Cao; Theodore S Lawrence; Adam Johansson; James M Balter Journal: Phys Med Biol Date: 2021-02-09 Impact factor: 3.609
Authors: Rhys Carrington; John Staffurth; Samantha Warren; Mike Partridge; Chris Hurt; Emiliano Spezi; Sarah Gwynne; Maria A Hawkins; Thomas Crosby Journal: Radiat Oncol Date: 2015-11-19 Impact factor: 3.481