Mont Carlo study on validation of intraoperative radiation therapy accelerator (LIAC) head

Authors

10.22052/3.2.21

Abstract

With the development of science and technology in the medical field and need more than ever to accuracy and quality of treatment has been causer increase different radiotherapy methods. Almost the past two decade’s intraoperative radiation therapy (IORT) as one of the new techniques used to treat cancer patients. One of the problems with this method is obtaining accurate dosimetry, because neither before nor after surgery ray images taken from the area of patient data do not match exactly. Therefore, dosimetric characteristics for intraoperative dedicated radiation therapy accelerators in comparison of conventional accelerators are difficult. The main objective of this study was to investigate the LIAC head a light and portable intraoperative radiation therapy accelerator and dosimetry calculate its features. For this purpose, the LIAC head was simulated using Monte Carlo (MCNP). Then the percentage depth dose curves obtained for reference applicator (10 cm) in all accelerator energies using experimental measurements, simulation model was validated. All experimental measurements were done by 12MeV models of LIAC accelerator. Finally, some dosimetric parameters such as maximum absorbed dose (Dm), maximum depth dose (dm), R50, practical range (Rp < /sub>), dose profile and other dosimetric parameters evaluated for reference applicator in the all LIAC electron beam energies.The results of this work show that the LIAC accelerator is designed for intraoperative radiation therapy method.

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References

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