Your search keyword '"Yagiz Yedekci"' showing total 3 results

1. Automatic contouring using deformable image registration for tandem-ring or tandem-ovoid brachytherapy

Author

Yagiz Yedekci, Melis Gültekin, Sezin Yuce Sarı, and Ferah Yıldız

Subjects

deformable image registration, image-guided brachytherapy, cervical cancer, brachytherapy., Medicine

Published

2022

2. Evaluation of nanoDot optically stimulated luminescence dosimeter for cone-shaped small-field dosimetry of cyberknife stereotactic radiosurgery unit: A monte carlo simulation and dosimetric verification study

Author

Fadil Akyol, Neslihan Sarigul, Mete Yeginer, Yagiz Yedekci, and Haluk Utku

Subjects

CyberKnife SRS unit, Monte Carlo simulation, nanoDot optically stimulated luminescence dosimeter, small-field dosimetry, Medical physics. Medical radiology. Nuclear medicine, R895-920

Abstract

Aim: The aim of this study was to investigate the adequacy of nanoDot optically stimulated luminescence (OSL) dosimeter for small field dosimetry before its in vivo applications in CyberKnife SRS unit. Materials and Methods: A PTW 60018 SRS Diode, 60019 microDiamond, and Gafchromic EBT3 films were used along with a nanoDot carbon-doped aluminum oxide OSL dosimeter to collect and compare beam data. In addition, the EGSnrc/BEAMnrc code was employed to simulate 6-MV photon beams of CyberKnife SRS system. Results: All detectors showed good consistency with each other in output factor measurements for cone sizes of 15 mm or more. The differences were maintained within 3% for these cones. However, OSL output factors showed higher discrepancies compared to those of other detectors for smaller cones wherein the difference reached nearly 40% for cone size of 5 mm. Depending on the performance of OSL dosimeter in terms of output factors, percentage depth doses (PDDs) were only measured for cones equal to or larger than 15 mm. The differences in PDD measurements were within 5% for depths in the range of 5–200 mm. Conclusion: Its low reliable readings for cones smaller than 15 mm should be considered before its in vivo applications of Cyberknife system.

Published

2019

3. The dosimetric impact of implants on the spinal cord dose during stereotactic body radiotherapy

Author

Altug Yucekul, Mustafa Cengiz, Gokhan Demirkiran, Melis Gultekin, Gokhan Ozyigit, Gozde Yazici, Sumerya Duru Birgi, Pervin Hurmuz, Muharrem Yazici, Fazli Yagiz Yedekci, and Sezin Yuce Sari

Subjects

medicine.medical_specialty, Stereotactic body radiotherapy, medicine.medical_treatment, Lumbar vertebrae, Radiosurgery, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Lumbar, medicine, Humans, Radiology, Nuclear Medicine and imaging, Corpectomy, Radiation treatment planning, Radiometry, Lumbar Vertebrae, Spinal Neoplasms, business.industry, Research, Radiotherapy Dosage, Prostheses and Implants, Models, Theoretical, Spinal cord, Vertebra, Spinal implant, medicine.anatomical_structure, Oncology, Spinal Cord, Radiology Nuclear Medicine and imaging, 030220 oncology & carcinogenesis, Thermoluminescent dosimeter, Radiology, Implant, business

Abstract

Background The effects of spinal implants on dose distribution have been studied for conformal treatment plans. However, the dosimetric impact of spinal implants in stereotactic body radiotherapy (SBRT) treatments has not been studied in spatial orientation. In this study we evaluated the effect of spinal implants placed in sawbone vertebra models implanted as in vivo instrumentations. Methods Four different spinal implant reconstruction techniques were performed using the standard sawbone lumbar vertebrae model; 1. L2-L4 posterior instrumentation without anterior column reconstruction (PI); 2. L2-L4 anterior instrumentation, L3 corpectomy, and anterior column reconstruction with a titanium cage (AIAC); 3. L2-L4 posterior instrumentation, L3 corpectomy, and anterior column reconstruction with a titanium cage (PIAC); 4. L2-L4 anterior instrumentation, L3 corpectomy, and anterior column reconstruction with chest tubes filled with bone cement (AIABc). The target was defined as the spinous process and lamina of the lumbar (L) 3 vertebra. A thermoluminescent dosimeter (TLD, LiF:Mg,Ti) was located on the measurement point anterior to the spinal cord. The prescription dose was 8 Gy and the treatment was administered in a single fraction using a CyberKnife® (Accuray Inc., Sunnyvale, CA, USA). We performed two different treatment plans. In Plan A beam interaction with the rod was not limited. In plan B the rod was considered a structure of avoidance, and interaction between the rod and beam was prevented. TLD measurements were compared with the point dose calculated by the treatment planning system (TPS). Results and discussion In plan A, the difference between TLD measurement and the dose calculated by the TPS was 1.7 %, 2.8 %, and 2.7 % for the sawbone with no implant, PI, and PIAC models, respectively. For the AIAC model the TLD dose was 13.8 % higher than the TPS dose; the difference was 18.6 % for the AIABc model. In plan B for the AIAC and AIABc models, TLD measurement was 2.5 % and 0.9 % higher than the dose calculated by the TPS, respectively. Conclusions Spinal implants may be present in the treatment field in patients scheduled to undergo SBRT. For the types of implants studied herein anterior rod instrumentation resulted in an increase in the spinal cord dose, whereas use of a titanium cage had a minimal effect on dose distribution. While planning SBRT in patients with spinal reconstructions, avoidance of the rod and preventing interaction between the rod and beam might be the optimal solution for preventing unexpectedly high spinal cord doses.

Published

2016