• 한국의학물리학회지:의학물리
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• 제18권4호
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• pp.226-232
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• 2007

국립암센터에 설치된 양성자 치료기의 빔 전달 시스템에 대하여 Geant4 코드를 이용하여 몬테카를로 전산모사를 수행하였고, 선량검증 도구로써의 이용 가능성에 대하여 연구하였다. 몬테카를로 기술을 기반으로 하는 선량계산은 물질내의 선량분포를 이해하는 데 가장 정확한 방법으로 알려져 있다 외부조사 방사선치료에 있어서 이 방법의 장점을 극대화 하기 위해서는, 빔이 지나가는 곳에 놓여진 노즐 구성요소들의 정확한 모델링과 더불어 초기빔 특성파악은 무엇보다 중요하다. 국립암센터에 설치된 양성자 치료기는 총 3가지 형태-double/single scattering, uniform scanning and pencil-beam scanning-로 치료빔을 조사할 수 있으며, 본 연구진은 Geant4.8.2 코드를 기반으로 double/single scattering 모드를 구성하는 모든 노즐구성요소들에 대하여 모델링 하였다. 특정 치료감이에 대하여 실험치와 일치하는 전산모사의 결과를 얻었다 본 기관에 설치된 양성자치료기에 대한 몬테카를로 전산모사에 대한 기반을 성공적으로 구축하였고, 치료빔에 대하여 정밀한 선량측정에 이용할 수 있다. 치료빔의 전 에너지 영역에 걸쳐 추가적인 커미셔닝을 수행할 것이다.

• 한국의학물리학회지:의학물리
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• 제19권1호
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• pp.35-41
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• 2008

양성자치료는 양성자의 물리적 특성으로 인해 인체 내의 특정범위에 모든 에너지를 전달하고 감쇠되어 타겟조직 뒤에 존재하는 정상조직에는 방사선이 조사되지 않는 큰 장점을 가진 치료법이다. 이 방법은 인체 내의 암 조직을 타겟으로 했을 때, 빔 방향에서의 타겟의 2차원적인 모양은 황동으로 제작된 블럭을 통해 정상조직에 들어가는 방사선을 차폐하고 마진을 주어서 GTV (eross Tumor Volume)에 90% 이상의 선량이 전달되도록 조절한다. 그리고, 양성자 빔의 날줄방향 (longitudinal)에서의 타겟의 3차원적인 모양을 고려하여 PMMA로 이루어진 보상체(compensator)를 밀링머신으로 조각하여 타겟에 방사선이 정확하게 분포되도록 한다. 이러한 보상체의 정확한 정도 관리를 위해 현재 사용되는 수동적인 방법을 보완하여 X선 영상으로 해당하는 보상체의 영상을 획득하여 이 영상을 기반으로 정도관리를 할 수 있는 방법을 제안하였고, 제안한 방법으로 보상체의 각각의 깎여진 평면의 모양과 두께를 정성적으로 비교 및 평가할 수 있었으며 두 영상의 차이가 80% 이상 맞는 것으로 확인되었다. 이를 바탕으로 영상을 이용한 정도관리 프로그램을 보완하여 추후 실제 양성자치료 정도관리에 사용될 예정이다.

• Nuclear Engineering and Technology
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• 제54권9호
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• pp.3422-3428
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• 2022

The prompt gamma imaging (PGI) technique is considered as one of the most promising approaches to estimate the range of proton beam in the patient and unlock the full potential of proton therapy. In the PGI technique, a dedicated algorithm is required to estimate the range of the proton beam from the prompt gamma (PG) distribution acquired by a PGI system. In the present study, a new range estimation algorithm was developed for a multi-slit prompt-gamma camera, one of PGI systems, to estimate the range of proton beam with high accuracy. The performance of the developed algorithm was evaluated by Monte Carlo simulations for various beam/phantom combinations. Our results generally show that the developed algorithm is very robust, showing very high accuracy and precision for all the cases considered in the present study. The range estimation accuracy of the developed algorithm was 0.5-1.7 mm, which is approximately 1% of beam range, for 1×10⁹ protons. Even for the typical number of protons for a spot (1×10⁸), the range estimation accuracy of the developed algorithm was 2.1-4.6 mm and smaller than the range uncertainties and typical safety margin, while that of the existing algorithm was 2.5-9.6 mm.

• Nuclear Engineering and Technology
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• 제37권5호
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• pp.433-446
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• 2005

The development of accelerator science and technology has been accommodating ever increasing demand from scientific community of the beam energy and intensity of proton beams. The use of high-powered proton beams has extended from the traditional application of nuclear and high-energy physics to other applications, including spallation neutron source replacing nuclear reactor, nuclear actinide transmutation, energy amplification reactors. This article attempts to review development of proton accelerator, both linear and circular, and issues related to the proton beam energy, intensity as well as its output power. For related accelerator physics and technical review, one should refer to the recent article in the Reviews of Modem Physics [1]

• 한국미생물·생명공학회지
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• 제38권3호
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• pp.235-243
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• 2010

For decades, traditional mutation breeding technologies using spontaneous mutation, chemicals, or conventional radiation sources have contributed greatly to the improvement of crops and microorganisms of agricultural and industrial importance. However, new mutagens that can generate more diverse mutation spectra with minimal damage to the original organism are always in need. In this regard, ion beam irradiation, including proton-, helium-, and heavier-charged particle irradiation, is considered to be superior to traditional radiation mutagenesis. In particular, it has been suggested that ion beams predominantly produce strand breaks that often lead to mutations, which is not a situation frequently observed in mutagenesis induced by gamma-ray exposure. In this review, we briefly describe the general principles and history of particle accelerators, and then introduce their successful application in ion beam technology for the improvement of crops and microbes. In particular, a 100-MeV proton beam accelerator currently under construction by the Proton Engineering Frontier Project (PEFP) is discussed. The PEFP accelerator will hopefully prompt the utilization of ion beam technology for strain improvement, as well as for use in nuclear physics, medical science, biology, space technology, radiation technology and basic sciences.

• 대한방사선치료학회지
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• 제25권2호
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• pp.107-113
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• 2013

목 적: 호흡동조 시스템을 이용한 양성자치료 시 생성되는 양성자빔을 측정하고 분석함으로써 호흡동조 양성자치료의 정확성을 검증하고자 한다. 대상 및 방법: 호흡동조 양성자치료를 실시한 환자 세 명의 치료계획을 이용하여 양성자 치료 시스템에서 양성자빔을 생성했다. 이때 자체 제작한 구동 팬톰을 사용하여 호흡동조 시스템을 적용해 분할 조사되는 양성자빔을 재현하였다. 양성자빔의 중요특성인 Range, Spread-Out Bragg Peak (SOBP), Output factor를 각 5회씩 측정하였으며 호흡동조 시스템을 적용하지 않은 연속 양성자빔에서도 동일한 항목들을 측정했다. Range와 SOBP 측정에는 Multi-Layer Ionization Chamber, Output factor 측정에는 Scanditronix Wellhofer와 Farmer chamber를 사용했다. 결 과: 호흡동조 시스템을 적용한 경우 세 환자의 평균 Range는 7.226, 12.216, 19.918 $g/cm^2$, SOBP는 4.950, 6.496, 8.486 $g/cm^2$, Output factor는 0.985, 1.026, 1.138 cGy/MU였으며, 적용하지 않은 경우 평균 Range는 7.230, 12.220, 19.920 $g/cm^2$, SOBP는 4.940, 6.512, 8.490 $g/cm^2$, Output factor는 0.984, 1.027, 1.136 cGy/MU로 측정됐다. 평균 Range의 차는 -0.004, -0.004, -0.002 $g/cm^2$, SOBP는 0.010, -0.016, -0.004 $g/cm^2$, Output factor는 0.001, -0.001, 0.002 cGy/MU로 나타났다. 결 론: 호흡동조 양성자치료 시 분할 조사된 양성자빔과 연속 조사된 양성자빔의 Range, SOBP 및 Output factor 모두 차이가 미미했다. 따라서 본 연구를 통해 호흡동조 시 발생된 양성자빔의 선질을 검증하였고 이를 이용한 양성자치료의 정확성 또한 확인할 수 있었다.

• Nuclear Engineering and Technology
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• 제52권9호
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• pp.2064-2071
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• 2020

For proton pencil beam scanning (PBS) technology, the accuracy of the dose distribution in a patient is sensitive to the properties of the incident beam. However, mechanical deformation of the proton therapy facility may occur, and this could be an important factor affecting the proton dose distribution in patients. In this paper, we investigated the effect of deformation on an SC200 proton facility's beam isocenter properties. First, mechanical deformation of the PBS nozzle, L-shape plate, and gantry were simulated using a Finite Element code, ANSYS. Then, the impact of the mechanical deformation on the beam's isocenter properties was evaluated using empirical formulas. In addition, we considered the simplest case that could affect the properties of the incident beam (i.e. if only the bending magnet (BG3) has an error in its mounting alignment), and the effect of the beam optics offset on the isocenter characteristics was evaluated. The results showed that the deformation of the beam position in the X and Y direction was less than 0.27 mm, which meets the structural design requirements. Compared to the mechanical deformation of the L-shape plate, the deformation of the gantry had more influence on the beam's isocenter properties. When the error in the mounting alignment of the BG3 is equal to or more than 0.3 mm, the beam deformation at the isocenter exceeds the maximum accepted deformation limits. Generally speaking, for the current design of the SC200 scanning beam delivery system, the effects of mechanical deformation meet the maximum accepted beam deformation limits. In order to further study the effect of the incident beam optics on the isocenter properties, a fine-scale Monte Carlo model including factors relating to the PBS nozzle and the BG3 should be developed in future research.

• Carbon letters
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• 제24권
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• pp.55-61
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• 2017

Carbon micropatterns (CMs) were fabricated from a negative-type SU-8 photoresist by proton ion beam lithography and pyrolysis. Well-defined negative-type SU-8 micropatterns were formed by proton ion beam lithography at the optimized fluence of $1{\times}10^{15}ions\;cm^{-2}$ and then pyrolyzed to form CMs. The crosslinked network structures formed by proton irradiation were converted to pseudo-graphitic structures by pyrolysis. The fabricated CMs showed a good electrical conductivity of $1.58{\times}10^2S\;cm^{-1}$ and a very low surface roughness.

• 한국작물학회지
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• 제56권3호
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• pp.250-254
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• 2011

The study was carried out to evaluate the affect of proton beam radiation on production of bulbil and tuber including change of endogenous gibberellins, of Dioscorea opposita Thunb. The yield of bulbils and tubers from non- and irradiated D. opposita Thunb at doses of 5, 10, 15 and 20 Gy were determined. Endogenous gibberellins were also quantified by GC/MS analysis. D. opposita tubers irradiated at 15 Gy produced higher bulbil production than non-irradiated plants. Enlarged bulbil (above size diameter 4 mm) was significantly increased at 15 Gy. Bioactive endogenous $GA_4$ was dominant in bulbils and tubers irradiated with proton beam rather than $GA_1$. Major gibberellins biosynthetic pathways in bulbils and tubers of D. opposita plants were non C-13 hydroxylation route. From the results of this study, 15 Gy proton beam radiation was suggested as an optimal dose that can produce high amounts of bulbil for mass production of D. opposita plant.

• 한국의학물리학회:학술대회논문집
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• 한국의학물리학회 2002년도 Proceedings
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• pp.180-182
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• 2002

A Proton Therapy Center was established this year in National Cancer Center, Korea. We chose IBA of Belgium as the vendor of the equipment package. A 230 MeV fixed-energy cyclotron will deliver proton beams into two gantry rooms, one horizontal beam room, and one experimental station. The building for the equipment is currently under design with a special emphasis on radiation shielding. Installation of equipments is expected to begin in September next year starting with the first gantry, and the acceptance test will be performed about a year later. To generate therapeutic radiation fields the wobbling method will be a main treatment mode for the first gantry. A pencil beam scanning system on the other hand will be equipped for the second gantry relying on the availability at the time of installation. The beam scanning with intensity modulation adapted will be a most advanced form in radiation therapy known as IMPT. Some details on the project progress, scope of the system, and design of building are described.