Study on Treatment Planning for the Prostate in Proton Therapy with Oxygen Enhancement Ratio Effect

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Study on Treatment Planning for the Prostate in Proton Therapy with Oxygen Enhancement Ratio Effect Seung Hoon Yoo, Hui Geng, Wai Wang Lam, Chi Wah Kong, Bin Yang, Tin Lok Chiu, Po Man Wu, Kin Yin Cheung and Siu Ki Yu Medical Physics and Research Department, Hong Kong Sanatorium & Hospital, Hong Kong, China

Dongho Shin Proton Therapy Center, National Cancer Center, Goyang 10408, Korea

Byung Jun Min∗ Department of Radiation Oncology, Chungbuk National University Hospital, Cheongju 28644, Korea (Received 28 April 2020; revised 26 June 2020; accepted 6 July 2020) The purpose of this study was to investigate the oxygen enhancement ratio (OER) effects on treatment planning for a hypoxic prostate tumor with proton scanning beams. Two different OERbased dose calculation models (the average model and the voxel model) were investigated by using hypoxic tumor models in this simulation study. For the hypoxic tumor model, an oxygen distribution with a range of 2.4–9.4 mmHg was used according to the clinical data. The results given by the average model and the voxel model were compared for 50% and 90% tumor control probabilities with variations in the hypoxic tumor volume and fractionation. Comparison between the treatment plans with OER-based higher predicted dose and with the conventional prescription dose was conducted to investigate the organ-at-risk (OAR) doses for the prostate case. The average model showed a higher calculated dose than the voxel model. The voxel model with a 50% control probability showed good agreement with the current prescription dose. The OER values of the average model ranged from 1.05 to 1.25, which were applied to the whole tumor volume in treatment planning. The voxel-model-based OERs were higher (1.50–1.75) than those of average model, and these OERs should be applied only for the hypoxic boost region. Regarding treatment plans, the doses of the rectum and the bladder were reduced to the tolerable range V80Gy (volume receiving equal to or greater than 80Gy) < 15% and V75Gy (volume receiving equal to or greater than 75Gy) < 15% respectively after an optimization, but the maximum dose to femoral heads was higher than 50 Gy. In conclusion, we investigated the possible ranges of the OER (1.3–1.8) for proton-beam treatment of prostate cases. A dose escalation of up to about 1.8 times can be applied for the small hypoxic region. This result, which was obtained using a model study, should be verified through clinical experiment. Keywords: OER, Proton therapy, Average model, Voxel model DOI: 10.3938/jkps.77.613

I. INTRODUCTION Compared to photon therapy, proton therapy has advantageous dose deposition properties resulting in a decrease in the irradiated volume of normal tissues. Proton therapy has been delivered in the past by using a passive system (passive scattering), but a more conformal and highly modulated beam has been created using active pencil-beam scanning (PBS) that overlay the target volume [1]. Proton therapy has become an increasingly utilized treatment for patients with prostate cancer [2–