• 한국의학물리학회지:의학물리
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• 제15권3호
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• pp.149-155
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• 2004

목적: 전립선암의 세기조절 방사선 치료 시, 조직의 밀도보정 여부가 선량분포에 끼치는 영향을 연구한다. 재료 및 방법: 5명의 전립선 암 환자에 대하여 6 MV와 10 MV의 광자선에 대하여 각각 치료계획을 수립하였다. 각각 의 계획에서 7개의 조사선이 설정되었고, 선량계산 시에는 체조직의 밀도의 불균일성을 무시하였다. 선량 처방점인 회전중심점에서의 흡수선량과 계획표적용적(PTV)의 최대선량, 최소선량, 평균선량과 처방점선량의 95% 이상의 받는 부피(V>$_{p95%}$) 등을 측정하였다. 직장과 방광 내에서의 최대선량, 최소선량, 최방선량의 50%, 75%, 90% 이상을 받는 부피를 측정하였다. 동일한 조건에서 조직의 밀도 불균일성을 포함하여 선량분포를 재계산하고, 측정한 모든 물리량을 재 측정하였다. 결과: 밀도보정을 함으로써, 처방점에서의 흡수 선량은 6 MV에서 평균 4.9% 10 MV에서는 평균 4% 감소하였다. V>$_{p95%}$는 6 MV와 10 MV에서 각각 0.8%와 0.9% 감소하였다. PTV의 평균 흡수 선량은 6 MV와 10 MV에서 각각 4.2% 와 3.4% 감소하였다. 직장과 방광에서의 흡수선량은 약 l～2%의 차이를 보였다 결론: 전립선암의 세기변조 방사선치료시에 밀도보정을 무시하는 것은 표적에는 고려할 만한 선량의 차이를 유발하며, 주위의 위험장기에 미치는 영향은 미미하다.

• Radiation Oncology Journal
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• 제10권2호
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• pp.155-161
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• 1992

눈의 수정체는 방사선에 매우 예민한 장기이며 비교적 적은 선량에서도 백내장의 원인이 될 수 있다. 그러므로 두경부암의 방사선치료에서 수정체를 최대한 차폐하면서 병소에 집중 조사하는 방법이 개발되어야 한다. 저자는 안구의 표면에서 0.5 cm 깊이에 위치하며 폭 1 cm인 눈의 수정체를 최대한 차폐하면서 주위 병소를 치료하기 위하여 원자번호가 높은 차폐물질을 이용하였으며 최적조사조건은 측정실험을 통하여 결정하였고 이를 임상치료에 응용하였다. 수정체의 차폐기구는 제작하기 쉽고 차폐효과가 큰 혼합금속(Cerrobend)이 적당하였으며 두께 7.5 cm와 직경 1 cm의 원뿔기둥모양이 가장 이상적이었다. 차폐기둥의 밑면과 표면과의 거리가 l0 cm일 때 수정체에 가장 적은 선량이 부여되며 병소에는 비교적 많은 선량이 부여된다. 이때 각막(Cornea, 1 mm), 수정체 (Eye Lens, 5 mm), 망막(Retina, 25 mm) 및 병소(Tumor, 50 mm 이상)의 선량은 차폐물이 없을 때와 비교하여 각각 $10.0\%$, $15.2\%$, $21.5\%$ 및 $23.2\%$로 측정되었다.

• 한국의학물리학회:학술대회논문집
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• 한국의학물리학회 2002년도 Proceedings
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• pp.113-115
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• 2002

The Monte Carlo simulation method is a numerical solution to a problem that models objects interacting with other objects or their environment based upon simple object-object or object-environment relationships. In spite of its great accuracy, It was turned away because of long calculation time to simulate a model. But, it is used to simulate a linear accelerator frequently with the advance of computer technology. To simulate linear accelerator in Monte Carlo simulations, there are many parameters needed to input to Monte Carlo code. These data can be supported by a linear accelerator manufacturer. Although the model of a linear accelerator is the same, a different characteristic property can be found. Thus, we performed a commissioning process of 6MV photon beam in Varian 2300C/D model with BEAM/EGS4 Monte Carlo code. The head geometry data were put into BEAM/EGS4 data. The mean energy and energy spread of the electron beam incident on the target were varied to match Monte Carlo simulations to measurements. TLDs (thermoluminescent dosimeter) and radiochromic films were employed to measure the absorbed dose in a water phantom. Beam profile was obtained in 40cm${\times}$40cm field size and Depth dose was in 10cm${\times}$10cm. At first, we compared the depth dose between measurements and Monte Carlo simulations varying the mean energy of an incident electron beam. Then, we compared the beam profile with adjusting the beam radius of the incident electron beam in Monte Carlo simulation. The results were found that the optimal mean energy was 6MV and beam radius of 0.1mm was well matched to measurements.

• Radiation Oncology Journal
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• 제13권4호
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• pp.397-402
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• 1995

Purpose : To determine the perturbation effect in the tissue downstream from surface layers of lesions located in the air/tumor-tissue interface of larynx using 6MV photon beam. Materials and Methods : Thermoluminescent dosimeters(TLDs), were embedded at 3 measurement locations in slab no. 7 of a humanoid phantom and exposed to forward and backward direction using various field sizes($4{\times}4cm^2\;-\;15{\times}15cm^2$). Results : At the air/tissue interface, forward dose perturbation factor(FDPF) is about 1.085 with $4{\times}4cm^2,\;1.05\;with\;7{\times}7cm^2,\;1.048\;with\;10{\times}10cm^2$ and $1.041\;with\;15{\times}15cm^2$. Backscatter dose perturbation factor(BDPF) is about 0.99 with $4{\times}4cm^2$, 0.981 with $7{\times}7cm^2$, 0.956 with $10{\times}10cm^2$ and 0.97 with $15{\times}15cm^2$. Conclusion : FDPF is greater as field size is smaller. And FDPF is smaller as the distance is further from the air/tissue interface.

• 한국의학물리학회:학술대회논문집
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• 한국의학물리학회 2002년도 Proceedings
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• pp.106-108
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• 2002

Recent advances in radiation transport algorithms, computer hardware performance, and parallel computing make the clinical use of Monte Carlo based dose calculations possible. Monte Carlo treatment planning requires accurate beam information as input to generate accurate dose distributions. The procedures to obtain this accurate beam information are called "commissioning", which includes accelerator head modeling. In this study, we would like to investigate how much accurately Monte Carlo based dose calculations can predict the measured beam data in various conditions. The Siemens 6MV photon beam and the BEAM Monte Carlo code were used. The comparisons including the percentage depth doses and off-axis profiles of open fields and wedges, output factors will be presented.

• 한국의학물리학회지:의학물리
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• 제15권1호
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• pp.23-29
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• 2004

CT관전압 및 기종의 변화에 따른 전자밀도 환산곡선 값의 변화가 상용 전산화치료계획장치의 선량계산 결과에 미치는 영향을 고찰하였다. CT기종 및 관전압을 달리하며 전자밀도 환산용 팬톰에 대한 CT 영상을 얻어서 여러 조직등가물질에 대해 전자밀도와 CT수의 관계를 구하였다. 동일 전자밀도에 대해 관전압이 감소함에 따라 고밀도의 골조직으로 갈수록 큰 CT수를 보였으며, 연조직에서는 거의 차이가 없었다. 전자밀도 환산곡선 값의 변화가 선량계산 결과에 미치는 정도를 알아보기 위하여 치료계획장치 상에서 폐조직과 골조직을 포함하는 물 팬톰을 그려서 만들고, 이들 가상 조직의 후방 위치에서 6 MV 광자선에 의한 선량을 계산하였다. 그 결과 폐조직, 물, 골조직의 순서로 선량이 높았으며, 골조직에 의한 선량은 관전압이 낮을수록 높은 값을 보였고, 이는 10 MV의 경우에도 동일하였다. 임상 적용의 예로서 폐 및 골반 부위의 CT 영상을 이용한 선량계산에서는 6 MV 및 10 MV모두 전자밀도 환산곡선 값의 변화에 따른 차이는 없었으며, 전자밀도 환산곡선을 구하는데 이용한 CT 기기와 선량을 계산하는데 이용한 영상을 얻은 CT 기기가 다른 데서 오는 것으로 판단되는 오차로서 최대 1.5%의 상대선량차이를 보였다.

• Journal of Radiation Protection and Research
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• 제42권1호
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• pp.9-15
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• 2017

Background: The purpose of this study is to assign an appropriate density to virtual phantom for 2D diode array detector with different dose calculation algorithms to guarantee the accuracy of patient-specific QA. Materials and Methods: Ten VMAT plans with 6 MV photon beam and ten VMAT plans with 15 MV photon beam were selected retrospectively. The computed tomography (CT) images of MapCHECK2 with MapPHAN were acquired to design the virtual phantom images. For all plans, dose distributions were calculated for the virtual phantoms with four different materials by AAA and AXB algorithms. The four materials were polystyrene, 455 HU, Jursinic phantom, and PVC. Passing rates for several gamma criteria were calculated by comparing the measured dose distribution with calculated dose distributions of four materials. Results and Discussion: For validation of AXB modeling in clinic, the mean percentages of agreement in the cases of dose difference criteria of 1.0% and 2.0% for 6 MV were $97.2%{\pm}2.3%$, and $99.4%{\pm}1.1%$, respectively while those for 15 MV were $98.5%{\pm}0.85%$ and $99.8%{\pm}0.2%$, respectively. In the case of 2%/2 mm, all mean passing rates were more than 96.0% and 97.2% for 6 MV and 15 MV, respectively, regardless of the virtual phantoms of different materials and dose calculation algorithms. The passing rates in all criteria slightly increased for AXB as well as AAA when using 455 HU rather than polystyrene. Conclusion: The virtual phantom which had a 455 HU values showed high passing rates for all gamma criteria. To guarantee the accuracy of patent-specific VMAT QA, each institution should fine-tune the mass density or HU values of this device.

• 대한방사선치료학회지
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• 제10권1호
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• pp.11-22
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• 1998

The absolute absorbed dose can be determined according to the measurement conditions ; measurement material, detector, energy and calibration protocols. The purpose of this study is to compare the absolute absorbed dose due to the differences of measurement condition and calibration protocols for photon beams. Dosimetric measurements were performed with a farmer type PTW and NEL ionization chambers in water, solid water, and polystyrene phantoms using 6MV photon beams from Siemens linear accelerator. Measurements were made along the central axis of $10{\times}10cm$ field size for constant target to surface distance of 100cm for water, solid water and polystyrene phantom. Theoretical absorbed dose intercomparisons between TG21 and IAEA protocol were performed for various measurement combinations on phantom, ion chamber, and electrometer. There were no significant differences of absorbed dose value between TG2l and IAEA protocol. The differences between two protocols are within $1\%\;while\;the\;average\;value\;of\;IAEA\;protocol\;was\;0.5\%$ smaller than TG2l protocol. For the purpose of comparison, all the relative absorbed dose were nomalized to NEL ion chamber with Keithley electrometer and water phantom, The average differences are within $1\%,\;but\;individual\;discrepancies\;are\;in\;the\;range\;of\;-2.5\%\;to\;1.2\%$ depending upon the choice of measurement combination. The largest discrepancy of $-25\%$ was observed when NEL ion chamber with Keithley electrometer is used in solid water phantom. The main cause for this discrepancy is due to the use of same parameters of stopping power, absorption coefficient, etc. as used in water phantom. It should be mentioned that the solid water phantom is not recommended for absolute dose calibration as the alternative of water, since absorbed dose show some dependency on phantom material other than water. In conclusion, the trend of variation was not much dependent on calibration protocol. However, It shows that absorbed dose could be affected by phantom material other than water.

• 대한안전경영과학회지
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• 제16권4호
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• pp.433-439
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• 2014

Beam quality is changed about magnetic field of bending magnet. Evaluation of beam quality using PDD(Percentage Depth Dose) at 10cm depth at recommendation of AAPM(America Academy of Pain Medicine). However this evaluation shows fragmentary element. Therefore this study is applied to three value, 10cm divided by 5cm depth PDD, 20cm divided by 10cm depth PDD, 30cm divided by 20cm depth PDD, at change the magnetic field. PDD is measured at magnetic field changed ${\pm}1%$, ${\pm}2%$ at 6MV(Mega Voltage), 10MV photon. The plan technique is 3 portal plan using Core-Plan at human pelvic phantom. Conventional and presented methods are compared at maximum and minimum dose. The presented method increased discernment of relieve the unequal distribution and energy area than conventional method. Henceforth, application of presented method will be considered. Development of energy measurement method and detector miniaturization will be needed about continuous study.

• 대한방사선치료학회지
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• 제1권1호
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• pp.37-42
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• 1985

Radiation Therapy(RT) has been used in the treatment of breast cancer for over 80 years. Technically, it should include a part or all of such areas as chest wall or breast, axilla, internal mammary nodes(IM) and supraclavicular nodes (SCL). Authors tried three-field technique for the treatment of breast cancer using 6 MV linear accelerator, exclusively the department of Radiology, Kang-Nam St. Mary's Hospital, at Catholic Medical College. The field junction was checked by a phantom study and radiation doses measured by film densitometry and TLD. The 3 fields we used in this study were two isocentric opposing tangential fields encompassing the breast, chest wall and occasionally IM and one single anterior field encompassing the axilla and SCL. Using appropriate beam blocks and blouses, we were able to avoid unwanted intrinsic divergency of photon beam. Blocking also enabled us to set-up precise radiation field with ease.