ESTRO 2023 - Abstract Book

S1611

Digital Posters

ESTRO 2023

Medical Center+, GROW School for Developmental Biology and Oncology, GROW School for Oncology, Maastricht University Medical Centre+, Maastricht, The Netherlands Purpose or Objective Radiotherapy in proximity of (peri)orbital structures is challenging due to the complexity, dose-sensitiveness, and mobility of these structures. To ascertain whether movement and position of optical structures are significant in treatment planning and execution, knowledge of the extent of movement is necessary to evaluate the margin for these organs-at-risk (PRV). This study aimed to quantify the intra- and inter-patient movement of 7 optical structures during the course of radiotherapy treatment. Materials and Methods Retrospectively, 10 neuro-oncological patients treated with proton therapy without any orbital conditions or morbidities were included. These patients received 5 weekly CTs (reCT) additional to the planning CT (pCT) as part of their regular treatment. For each CT, 7 optical structures were delineated bilaterally using the EPTN-atlas (Eekers 2018, Eekers 2021): cornea, fovea, lacrimal gland, lens, macula, optic nerve and retina. The delineation of the optic nerve was divided in 3 regions: distal and proximal intra-orbital and intra-cranial. As a control, both oculi were delineated; displacement observed in the oculi could indicate inaccuracies in image registration, delineation, or set-up. The eyelids’ status during CT were scored (open/closed). The reCT delineations were copied to the pCT by rigid registration and compared to the pCT delineation using Dice Similarity Coefficient (DSC), volume difference reCT-pCT ( Δ V), and midpoint difference ( Δ MP). Reported are the median, 5th and 95th percentiles. Results The left retina had the highest 95th percentile DSC (0.90) but also highest 95th Δ V (1.04cm3); the left macula the lowest 5th DSC (0.00). Within the optic nerve regions, Δ MP was highest for the proximal intra-orbital region (up to 3mm in Y direction). The left macula had the highest 95th Δ MPvector (4.6mm). The oculi Δ MPvector was at most 2mm. Highest 95th Δ MPx, Δ MPy, and Δ MPz were found for the left cornea (2.4mm), left fovea (3.8mm), and left optic nerve (1.7mm), respectively. Fig. 1 depicts the vDSC and Δ MP for a subset of structures. In general, Δ MPy was greater than Δ MPx and Δ MPz. Closed eyes during CT showed more movement. An example patient with movement of the macula and intra-orbital optic nerve between pCT and reCT is shown in Fig. 2. A PRV-like margin was calculated from the 95th percentiles of Δ MP, representing the movement of structures for 95% of the reCTs. In this study, a PRV-margin of 3-4mm would be needed for the cornea, fovea, lenses, macula and proximal intra orbital optic nerves. Separate margins can be specified for X, Y, and Z-directions.