Affiliation:
1. Medical Radiation Department Shahid Beheshti University Tehran Iran
2. Radiotherapy Oncology Department Shohada Tajrish Educational Hospital Shahid Beheshti University of Medical Science Tehran Iran
3. Geneva University Neurocenter Geneva University Geneva Switzerland
4. Cancer Institute Tehran University of Medical Science Tehran Iran
5. Medical Physics Department Surrey University Guildford UK
Abstract
AbstractBackgroundOcular melanoma is a rare kind of eye malignancy that threatens the patient's eyesight. Radiotherapy and surgical removal are the most commonly used therapeutic modalities, and nanomedicine has lately entered this field. Brachytherapy using Ruthenium‐106 (106Ru) ophthalmic plaques has been used for decades to treat ocular melanoma, with the applicator placed on the patient's eyes until the prescribed dose reaches the tumor apex.PurposeTo investigate the efficiency of hydrogen nanobubbles (H2‐NBs) employment during intraocular melanoma brachytherapy using a 106Ru electron emitter plaque.MethodsThe Monte Carlo (MC) simulation and experimental investigation using a 3D‐designed phantom and thermoluminescence dosimetry (TLD) were employed. Various concentrations of H2‐NBs with a diameter of 100 nm were simulated inside tumor tissue. The results were presented as deposited energy and dose enhancement factor (DEF). An equivalent Resin phantom of the human eyeball was made using AutoCAD and 3D‐Printer technologies. The glass‐bead TLDs dosimeter were employed and placed inside the phantom.ResultsUsing a 1% concentration of H2‐NBs, a DEF of 93% and 98% were achieved at the tumor apex of 10 mm from the experimental setup and MC simulation, respectively. For simulated concentrations of 0.1%, 0.3%, 0.5%, 1%, and 4% H2‐NBs, a maximum dose enhancement of 154%, 174%, 188%, 200%, and 300% were achieved, respectively, and a dose reduction was seen at about 3 mm from the plaque surface.ConclusionH2‐NBs can be used as an absorbed dose enhancer in 106Ru eye brachytherapy because of their unique physical characteristics. Reducing plaque implantation time on the patient's eye, reducing sclera absorbed dose, and decreasing the risk of patients’ healthy organs irradiation are reported as some of the potential benefits of using H2‐NBs.
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