Your search keyword '"Elham Hoseinnezhad Zarghani"' showing total 3 results

1. Evaluation of dose uniformity in total body irradiation (TBI) technique in parallel-opposed anterior/posterior geometry using Varian Clinac 2100C/D linear accelerator

Author

Elham Hoseinnezhad Zarghani, Ghazale Geraily, Mahbod Esfahani, and Mostafa Farzin

Subjects

dose uniformity, film dosimetry, whole-body irradiation, Medicine (General), R5-920

Abstract

Background: Total body irradiation (TBI) is a technique that is commonly used as a part of the patient conditioning regimen before the bone marrow transplant (BMT). The purpose of this study is to introduce and implement a reasonable TBI technique on the human-like phantom in Imam Khomeini Hospital in Tehran. Methods: The present experimental study was conducted from October 2016 to November 2017 to implement the TBI technique at the Cancer Institute of Imam Khomeini Hospital in Tehran. For this purpose, percentage depth dose, and dose rate were measured in TBI condition (i.e. SSD=310 cm, field size=40×40 cm2, gantry angle=90°, and collimator angle 45°) in homogeneous phantom. Gafchromic EBT3 films were used to measure the absorbed dose in different areas of the human like phantom at the levels of head, neck, thyroid, lung, umbilicus, pelvic, thigh, knee and leg. Phantom irradiation was performed in parallel opposed anterior-posterior geometry using an 18MV photon beam produced by Varian 2100C/D. Cerrobend blocks were used for lung protection. After analyzing the exposed films with Image J software, the dose uniformity was calculated. Results: Dose distribution uniformity was acquired in the order of -1.01% to +11.82% relative to the prescribed dose at the umbilicus. The difference between the calculated and measured dose at the umbilicus level was -2.73%. The radiation absorbed dose to the lung with blocks was 127.53cGy in one fraction which resulted in 756.18cGy in six fractions. Conclusion: The implemented technique, obtained the acceptable ±10% dose uniformity in most of the body regions. The dosing accuracy was within the acceptable range. The lungs¢ dose was reduced to the desired level using lung shields. This technique is a simple and cost-effective method that does not require complicated dosimetric techniques. Regarding the obtained results, the proposed technique has the necessary conditions for implementation in Imam Khomeini hospital in Tehran.

Published

2020

2. Dosimetric comparison of AP/PA and bilateral geometries for total body irradiation treatment

Author

Mohammad Kazem Amini, Ali Rastjoo, Ghazale Geraily, Mahbod Esfahani, Mostafa Farzin, Peiman Haddad, and Elham Hoseinnezhad Zarghani

Subjects

Dose delivery, Monitor unit, Radiation, Materials science, business.industry, Biophysics, Dose accuracy, Source surface, Total body irradiation, Imaging phantom, Absorbed dose, Dosimetry, Nuclear medicine, business, General Environmental Science

Abstract

Total body irradiation (TBI) is an external radiotherapy technique. Its aim is to deliver a therapeutic dose uniformly within ± 10% of the absorbed dose to the prescription point. In the present study, the TBI technique was implemented in anterior/posterior (AP/PA), and bilateral geometry with photons from a 6 $$\mathrm{MV}$$ and 18 $$\mathrm{MV}$$ accelerator. The TBI technique was implemented on an Alderson Rando phantom at 312 $$\mathrm{cm}$$ source surface distance. During bilateral fraction, rice bags were applied as tissue compensators. To reduce the lung’s absorbed dose to the acceptance level, in AP/PA geometry lung blocks made of Cerrobend were used. The required monitor unit (MU) for each fraction was calculated regarding depending on the prescribed dose and beam output. Gafchromic EBT3 films were used for dosimetry between the phantom layers in eight selected points. It is demonstrated that dose uniformity for AP/PA geometry with 6 $$\mathrm{MV}$$ and 18 $$\mathrm{MV}$$ photons was within ± 10%. In contrast, for the bilateral geometry the dose uniformity was not acceptable for both studied energies; However, the results for 18 $$\mathrm{MV}$$ were better than those for 6 $$\mathrm{MV}$$ . Dose accuracy for all measurements was within ± 5 of the prescribed dose. The absorbed dose to the lungs was successfully reduced using the lung blocks. By combining different therapeutic geometries and energies over six fractions, the results of uniformity and accuracy of dose delivery could be improved. It is concluded that the introduced TBI method achieved good dose accuracy and acceptable dose uniformity. Lungs absorbed dose was lower than 10 $$\mathrm{Gy}$$ using the lungs blocks. Based on these results, the TBI technique can now be implemented in radiotherapy at Tehran’s Imam Hospital. The approach developed in the present study can be used and adapted to match with the conditions at other hospitals.

Published

2021

3. Dosimetric comparison of AP/PA and bilateral geometries for total body irradiation treatment

Author

Elham, Hoseinnezhad Zarghani, Ghazale, Geraily, Peiman, Haddad, Mahbod, Esfahani, Mostafa, Farzin, Ali, Rastjoo, and Mohammad Kazem, Amini

Subjects

Phantoms, Imaging, Radiotherapy Planning, Computer-Assisted, Radiotherapy Dosage, Iran, Radiometry, Whole-Body Irradiation

Abstract

Total body irradiation (TBI) is an external radiotherapy technique. Its aim is to deliver a therapeutic dose uniformly within ± 10% of the absorbed dose to the prescription point. In the present study, the TBI technique was implemented in anterior/posterior (AP/PA), and bilateral geometry with photons from a 6 [Formula: see text] and 18 [Formula: see text] accelerator. The TBI technique was implemented on an Alderson Rando phantom at 312 [Formula: see text] source surface distance. During bilateral fraction, rice bags were applied as tissue compensators. To reduce the lung's absorbed dose to the acceptance level, in AP/PA geometry lung blocks made of Cerrobend were used. The required monitor unit (MU) for each fraction was calculated regarding depending on the prescribed dose and beam output. Gafchromic EBT

Published

2020