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Dose distribution assessment in human eye proton therapy by Monte Carlo method 1 Department of Physics, Faculty of Science, University of Isfahan, Isfahan, Iran. 2* Department of Biomedical Engineering, Faculty of Engineering, University of Isfahan, Isfahan, Iran Karimian@eng.ui.ac.ir M. Tavakol 1, A. Karimian 2*, S.M. Mostajab Aldaavati 1 10/10/20151
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www.amazingeye.com 10/10/20152 Eye and its anatomic structure
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Eye TumorsEye Tumors Tumors in the eye usually are secondary tumors caused by cancers that have spread from other parts of the body, especially the breast, lung, bowel or prostate. Two types of primary tumors arise within the eye itself and are known as retinoblastoma in children and melanoma in adults 10/10/2015 http://www.hopkinsmedicine.org/wilmer/conditions/tumors.html 3
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Retinoblastoma Retinoblastoma is a cancer of the retina. This most common childhood eye cancer usually strikes children under age five, affecting 500 to 600 in the United States each year. In nearly a third of the cases, retinoblastoma occurs in both eyes. 10/10/2015 http://www.hopkinsmedicine.org/wilmer/conditions/tumors.html 4
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melanoma Malignant melanoma occurs most frequently in adults 60 to 65 years of age, arising from uncontrolled growth of cells called melanocytes. From 1,500 to 2,000 new cases are diagnosed annually in the United States 10/10/20155
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Eye tumors affectsEye tumors affects In addition to damaging vision, eye tumors can spread to the optic nerve, the brain and the rest of the body. Melanoma tends to spread via blood vessels to distant organs Therefore, early diagnosis and treatment are extremely important. 10/10/20156
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Eye tumor treatment methodsEye tumor treatment methods There are various ways to treat eye tumors, depending on the size and aggressiveness of the tumor, and other factors. Surgery, Radiation Therapy, laser and cryosurgery may use for eye tumor treatment 10/10/20157
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Radiation therapy Internal radiation therapy Proton therapy 10/10/2015 Tele-therapy (LINAC, …) plaque therapy Brachytherapy 8
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Advantags of proton particles Noninvasive Small dimensions Focal Proton Particles Energetic but controlled Rather short-range Suitable Bragg Peak 10/10/20159
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Individual mask Block-Bite [http://www.triumf.info/public/tech_transfer/treatment.php]. Nozzle 10/10/201510
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In spite of the advantages of proton therapy, during treatment, the tumor and also other components of vision like optic nerve, cornea, lens, anterior chamber are subjected to the radiation. Malignant melanomas appear most commonly in the choroid 10/10/201511
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In this research, one proton therapy system belonging to the Laboratori Nazionali del Sud- INFN as well as the human eye and its components were simulated by Monte Carlo method. Maximum proton energy beam = 250 MeV Proton beam radius = 0.5 cm Modifier thickness = 1.5 cm Number of particles per second = 1.25 E+10 In this research: Energy for eye = ( 50 – 65 ) MeV Proton beam radius = ( 0.6 - 0.8 ) cm Modifier thickness = ( 1 - 1.9 ) cm 10/10/201512
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To assess the absorbed dose in different parts of eye, the proton therapy system, the nuzzle aperture, modifier, different parts of eye such as choroid and sclera, retina and etc, also vision sense parts such as optic nerve, cornea, lens and anterior chamber were simulated by Monte Carlo method. The eye was simulated by considering real materials and densities of eye components such as lens, cornea, retina, anterior chamber. 10/10/201513
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Optic nerve Vitreous Lens Anterior chamber Cornea 10/10/201514
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10/10/2015 Optic Nerve 15
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10/10/201516 Treatment view of choroid and sclera cancer
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The study was done in the following two stages, by changing the thickness of modifier in the range of 1.0 – 1.9 cm : I. A tumor with the radius of 0.28 cm in choroid region (cell 23) II. A tumor with the radius of 0.26 cm in choroid region and close to optic nerve (cell 27) 10/10/201517
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Radius tumor = 0.28 cm Volume tumor = 0.0914 cm 3 30 39 20 29 23 10/10/201518
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23 cell No.23 Radius tumor = 0.28 cm Volume tumor = 0.0914 cm 3 proton energy beam = 53.5 MeV Modifier thickness = 1.5 cm proton beam radius = 0.8 cm 10/10/2015 Dose (Gy) Cell No 19
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The calculated total dose (Gy) in this study for the tumor in the choroid and sclera regions (cell No.23) Cells 6.6410 2.5611 0.3912 7.9213 1.2814 43.1220 45.1221 47.5222 49.6823 47.1224 29.7625 8.2426 0.1227 028 029 0.007830 0.0003531 032 033 034 035 036 037 038 039 10/10/201520
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Radius tumor = 0.26 cm Volume tumor = 0.076 cm 3 30 39 20 29 27 10/10/201521
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27 cell No.27 Radius tumor = 0.26 cm Volume tumor = 0.076 cm 3 proton energy beam = 65 MeV modifier thickness = 1.5 cm proton beam radius = 0.5 cm Dose (Gy) Cell No 10/10/201522
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The calculated total dose (Gy) in this study for the tumor in the choroid and sclera regions (cell No.27) Cells 2.3210 0.3411 0.3312 20.0413 6.6414 43.220 42.5621 40.1622 3823 37.6824 40.425 47.626 49.3627 23.6828 6.2429 0.04630 0.03731 0.03832 0.01833 0.02134 0.02835 0.02436 0.005237 038 039 10/10/201523
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10/10/201524 This research showed in spite of the benefits of proton therapy in eye cancer treatment, the absorbed dose of healthy parts of eye specially the closed parts to the tumor are considerable and needs to reduce as much as possible. The absorbed dose depends on the energy of proton beam, modifier thickness, size and location of tumor, radiation angle, etc, Which can modify and improve by Monte Carlo method. proton energy beam modifier thickness proton beam radius Radius tumor Position tumor MeV 65cm 1.5cm 0.5cm 0.26Cell No.27 MeV 53.5cm 1.5cm 0.8cm 0.28Cell No.23 Conclusion
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10/10/201525 Thank you
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