ESTRO 2023 - Abstract Book

S641

Monday 15 May 2023

ESTRO 2023

Figure 2: FBG dosimeter response measured during pre-irradiation, during irradiation, and during post-irradiation for FBG #4 through FBG #16. Conclusion We developed an efficient technique to correct ambient temperature variations in real-time adapted to radiotherapy dose range using a multi-point FBG dosimeter, a first in our field. This opens the door to clinical FBG dosimetry applications. [1] Lebel-Cormier, M.A. and al. Sensors 2021, 21, 8139. OC-0774 Image quality of a proton radiography system using 2D lateral projections for image guidance M. Simard 1 , D. Robertson 2 , R. Fullarton 1 , A. Toltz 3 , C. Baker 3 , S. Beddar 4 , C. Collins-Fekete 1 1 University College London, Medical Physics & Biomedical Engineering, London, United Kingdom; 2 Mayo Clinic Arizona, Division of Medical Physics, Department of Radiation Oncology, Phoenix, USA; 3 University College London Hospital, NHS Foundation Trust, Radiotherapy Physics, London, United Kingdom; 4 The University of Texas MD Anderson Cancer Center, Radiation Physics, Houston, USA Purpose or Objective Image guidance is a necessary step to help proton therapy reach its full potential for the treatment of cancers such as non- small cell lung cancer. Using the treatment source to capture projection proton radiographs (pRads) is an attractive imaging solution, as it is registered with the treatment beam and limits water equivalent thickness (WET) errors. Proton imaging is typically achieved using single-event imaging, which is currently too slow for practical image guidance and generally not compatible with clinical beam settings. An alternative, integrated mode proton imaging, consists of acquiring signals from individual pencil beams (PB) using clinical beam parameters. The objective of this work is to report imaging quality of a low-cost and fast imaging device based on a volumetric scintillator and CCD cameras for integrated mode pRads. Image reconstruction is achieved by fully exploiting captured 2D lateral projections of the dose deposition in the scintillator. Materials and Methods Proton radiographs were acquired at Mayo Clinic Arizona using a plastic volumetric scintillator and a single CCD camera capturing a projected 2D lateral view of 3D energy deposition in the scintillator (Fig 1a). The device covers a 13x13 cm2 field of view. Image reconstruction is done using a novel reconstruction framework which identifies multiple candidate Bragg peaks in lateral views and performs a weighted reprojection of the WET according to Fermi-Eyges theory. Data was acquired using clinical settings at 135 MeV, and PB spacings of 2, 3, 4 and 5 mm. Results are presented for a 3 mm spacing which is a compromise between imaging time and quality. The following phantoms were scanned: Las Vegas (contrast), slanted edge (resolution), 9 tissue-substitute Gammex inserts (quantitative WET accuracy), and a paediatric head phantom. The reconstruction using projected 2D lateral views is compared with a conventional integrated mode system (1D Bragg curve). Results Clinical image quality of our reconstruction for the paediatric head phantom is shown in fig 1b. Compared to conventional integrated mode approach, our method yields a 30% relative increase in resolution (fig 1c. defined as 10% of the modulation transfer function) and a 60% relative increase of contrast (Fig 1d-e). Fig 2 illustrates an excellent WET accuracy (mean absolute error of 0.4 mm over all 9 inserts). Sub-second imaging can be achieved with a 6 mm beam sampling.