• Journal of Radiation Protection and Research
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• 제36권1호
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• pp.28-34
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• 2011

세기조절방사선치료(Intensity Modulated Radiotherapy, IMRT)의 정도관리를 위해서 독립적인 방법으로 선량검증을 하는 것은 중요하다. 독립적 선량검증을 위해 팬톰과 이온전리함을 이용한 측정 방법이 보편적으로 이루어지지만 많은 시간과 노력이 요구된다. 본 연구에서는 세기조절방사선치료 시 시간에 따른 다엽콜리메이터의 움직임을 기록한 dynalog 파일을 이용하여 치료계획에서 도출된 총 실제 플루언스와 실제 치료 시의 모니터유닛(monitor unit, MU) 공간분포를 비교함으로써 간편한 세기조절방사선치료 정도관리 기술을 개발하였다. DICOM RT plan 파일로부터 총 실제 플루언스를 추출하고 MATLAB 코드를 이용하여 실제 치료 시 MU 공간분포를 dynalog 파일로부터 계산하였다. 개발된 방법의 효용성을 검증하기 위해 단계별조사기법과 동적조사기법으로 치료 받은 각 5명의 환자 데이터를 후향적으로 분석하였다. 분석 방법은 상용프로그램(Verisoft 3.1, PTW, German)에서 제공하는 감마인덱스를 사용하였다. 분석 결과 실제 치료 시의 MU 공간분포와 치료계획 상의 MU 공간분포 일치도가 평균 $97.8{\pm}1.33$%로 높은 일치도를 나타냈다. MU 공간분포 재구성의 정확도는 동적조사기법보다 단계별조사기법이 평균 1.4% 높았다. 본 연구에서 개발된 기술을 통해 세기조절방사선치료의 선량검증을 효과적으로 수행할 수 있다. 또한 분할치료 시 선량보정에 적용함으로써 맞춤형치료(adaptive radiotherapy)를 위한 기초자료로 사용될 수 있을 것이다.

• 대한방사선기술학회지:방사선기술과학
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• 제43권1호
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• pp.9-14
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• 2020

Commercial plate bolus is generally used for treatment of surface tumor and required surface dose. We fabricated 3D-printed bolus by using 3D printing technology and usability of 3D-printed bolus was evaluated. RT-structure of contoured plate bolus in the TPS was exported to DICOM files and converted to STL file by using converting program. The 3D-printed bolus was manufactured with rubber-like translucent materials using a 3D printer. The dose distribution calculated in the TPS and compared the characteristics of the plate bolus and the 3D printed bolus. The absolute dose was measured inserting an ion chamber to the depth of 5 cm and 10 cm from the surface of the blue water phantom. HU and ED were measured to compare the material characteristics. 100% dose was distributed at Dmax of 1.5 cm below the surface when was applied without bolus. When the plate bolus and 3D-plate bolus were applied, dose distributed at 0.9 cm and 0.8 cm below the surface of the bolus. After the comparative analysis of the radiation dose at the reference depth, differences in radiation dose of 0.1 ~ 0.3% were found, but there was no difference dose. The usability of the 3D-printed bolus was thus confirmed and it is considered that the 3D-printed bolus can be applied in radiation therapy.

• 한국의학물리학회지:의학물리
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• 제27권4호
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• pp.196-202
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• 2016

We aim to develop the breast bolus by using a 3D printer to minimize the air-gap, and compare it to commercial bolus used for patients undergoing reconstruction in breast cancer. The bolus-shaped region of interests (ROIs) were contoured at the surface of the intensity-modulated radiation therapy (IMRT) thorax phantom with 5 mm thickness, after which the digital imaging and communications in mdicine (DICOM)-RT structure file was acquired. The intensity-modulated radiation therapy (Tomo-IMRT) and direct mode (Tomo-Direct) using the Tomotherapy were established. The 13 point doses were measured by optically stimulated luminescence (OSLD) dosimetry. The measurement data was analyzed to quantitatively evaluate the applicability of 3D bolus. The percentage change of mean measured dose between the commercial bolus and 3D-bolus was 2.3% and 0.7% for the Tomo-direct and Tomo-IMRT, respectively. For air-gap, range of the commercial bolus was from 0.8 cm to 1.5 cm at the periphery of the right breast. In contrast, the 3D-bolus have occurred the air-gap (i.e., 0 cm). The 3D-bolus for radiation therapy reduces the air-gap on irregular body surface that believed to help in accurate and precise radiation therapy due to better property of adhesion.