• 한국의학물리학회지:의학물리
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• 제27권3호
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• pp.105-110
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• 2016

Sparse angular sampling has been studied recently owing to its potential to decrease the radiation exposure from computed tomography (CT). In this study, we investigated the analytic reconstruction algorithm in sparse angular sampling using the sinogram interpolation method for improving image quality and computation speed. A prototype of the spectral CT system, which has a 64-pixel Cadmium Zinc Telluride (CZT)-based photon-counting detector, was used. The source-to-detector distance and the source-to-center of rotation distance were 1,200 and 1,015 mm, respectively. Two energy bins (23~33 keV and 34~44 keV) were set to obtain two reconstruction images. We used a PMMA phantom with height and radius of 50.0 mm and 17.5 mm, respectively. The phantom contained iodine, gadolinium, calcification, and lipid. The Feld-kamp-Davis-Kress (FDK) with the sinogram interpolation method and Maximum Likelihood Expectation Maximization (MLEM) algorithm were used to reconstruct the images. We evaluated the signal-to-noise ratio (SNR) of the materials. The SNRs of iodine, calcification, and liquid lipid were increased by 167.03%, 157.93%, and 41.77%, respectively, with the 23~33 keV energy bin using the sinogram interpolation method. The SNRs of iodine, calcification, and liquid state lipid were also increased by 107.01%, 13.58%, and 27.39%, respectively, with the 34~44 keV energy bin using the sinogram interpolation method. Although the FDK algorithm with the sinogram interpolation did not produce better results than the MLEM algorithm, it did result in comparable image quality to that of the MLEM algorithm. We believe that the sinogram interpolation method can be applied in various reconstruction studies using the analytic reconstruction algorithm. Therefore, the sinogram interpolation method can improve the image quality in sparse-angular sampling and be applied to CT applications.

• 전자공학회논문지
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• 제53권10호
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• pp.138-142
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• 2016

듀얼 에너지 디지털 촬영법 (dual-energy digital radiography, DEDR)은 에너지 감산법을 이용하여 신체 내 병변을 감지하는 데 사용 되어 왔다. 본 연구에서는 DEDR을 이용하여 관전압과 부가필터와 같은 물리적 인자를 변화시킴으로써 최적의 뼈와 조직 영상을 획득하고, SRS-78 프로그램으로 예측한 값과 비교하고자 한다. 에너지 감산법을 이용하여 뼈와 조직의 분리된 영상을 획득하기 위하여 다양한 물질의 물리적 인자의 변화에 따른 영상을 구하였다. 연구에 사용된 팬텀은 알루미늄과 polymethyl methacrylate (PMMA)로 구성되었으며, 영상의 최적화는 대조도 대 잡음비 (contrast-to-noise ratio, CNR)로 측정하였다. 실험 결과 50 kVp와 120 kVp 두 영상의 감산 영상이 최적의 뼈와 조직의 분리 영상임을 확인 할 수 있었다. 또한 고 에너지에 10 mm 알루미늄 부가필터를 추가하였을 때, 최적의 뼈와 조직의 분리 효과를 기대 할 수 있었다. 이러한 결과는 실험 전에 SRS-78 프로그램으로 예측한 최적화 조건과 일치함을 알 수 있었다. 본 연구를 통해 관전압이나 부가필터 두께와 같은 물리적 인자를 적절하게 조절한다면 최적의 영상을 얻을 수 있음을 확인하였고, DEDR을 이용하여 원하는 부분만을 표현함으로써 의료영상분야에 기여하고 응용분야를 확장 할 수 있을 것으로 기대한다.

• 한국의학물리학회:학술대회논문집
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• 한국의학물리학회 1999년도 Japanese Journal of Medical Physics
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• pp.278-281
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• 1999

The purpose of this study is to investigate the effect of the scattered x-rays on the subject contrast and image sharpness for various tube voltages. For the purpose, we measured the scatter-to-primary ratio(SPR) for the tube voltages f 50 to 100kV and obtained the tube voltage dependence of the subject contrast of an aluminum plate in a polymethyl methacrylate(PMMA) phantom. Furthermore, the overall modulation transfer functions(MTFs), which consist of MTFs of a screen-film system and scatter FTMs, were obtained for tube voltages of 50 to 100 kV. The subject contrast decreased with the tube voltage due to that the SPR increased with the tube voltage and that the difference in effective linear attenuation coefficients between the object and its surroundings decreased with the tube voltage. The maximum frequency of the overall MTF decreased from about 2 mm$\^$-1/ to 1 mm$\^$-1/ with the tube voltage increasing from 50 to 100 kV.

• 대한방사선기술학회지:방사선기술과학
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• 제43권5호
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• pp.353-357
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• 2020

IVR procedures are on the rise, and patient doses are on the rise. It is necessary to evaluate fluoroscopy dose in IVR procedure. Evaluate ESD on IVR equipment as a reference to DRL settings, I would like to present the direction of improvement in the ESD rate test criteria for fluoroscopy dose. The experimental method is measured with 6cc ionization chamber under the 20cm PMMA Phantom. Radiation is subject to abdominal procedure. The average dose rate of the incident surface was 21.6 ± 11.4 mGy/min. The highest dose equipment was 58.5 mGy/min, and there was no equipment exceeding the domestic standard of 100 mGy/min. However, there were five units above 50 mGy/min. To reduce fluoroscopy dose, it is recommended to reduce pulse rate, The dose increases as the image receptor ages. It is recommended to modify the domestic inspection criteria to 50 mGy/min.

• Nuclear Engineering and Technology
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• 제51권2호
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• pp.533-538
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• 2019

The mechanical-collimation imaging is the most mature technology in prompt gamma (PG) imaging which is considered the most promising technology for beam range verification in proton therapy. The purpose of the present study is to compare the performances of two mechanical-collimation PG cameras, knife-edge (KE) camera and multi-slit (MS) camera. For this, the PG cameras were modeled by Geant4 Monte Carlo code, and the performances of the cameras were compared for imaginary point and line sources and for proton beams incident on a cylindrical PMMA phantom. From the simulation results, the KE camera was found to show higher counting efficiency than the MS camera, being able to estimate the beam range even for $10^7$ protons. Our results, however, confirmed that in order to estimate the beam range correctly, the KE camera should be aligned, at least approximately, to the location of the proton beam range. The MS camera was found to show lower efficiency, being able to estimate the beam range correctly only when the number of the protons is at least $10^8$. For enough number of protons, however, the MS camera estimated the beam range correctly, errors being less than 1.2 mm, regardless of the location of the camera.

• Nuclear Engineering and Technology
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• 제55권1호
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• pp.215-221
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• 2023

Proton treatment may deliver a larger dose to a patient's skin than traditional photon therapy, especially when a range shifter (RS) is inserted in the beam path. This study investigated the effects of an RS on skin dose while considering RS with different thicknesses, airgaps and materials. First, the physical model of the scanning nozzle with RS was established in the TOol for PArticle Simulation (TOPAS) code, and the effects of the RS on the skin dose were studied. Second, the variations in the skin dose and isocenter beam size were examined by reducing the air gap. Finally, the effects of different RS materials, such as polymethylmethacrylate (PMMA), Lexan, polyethylene and polystyrene, on the skin dose were analysed. The results demonstrated that the current RS design had a negligible effect on the skin dose, whereas the RS significantly impacted the isocenter beam size. The skin dose was increased considerably when the RS was placed close to the phantom. Moreover, the magnitude of the increase was related to the thickness of the inserted RS. Meanwhile, the results also revealed that the secondary proton primarily contributed to the increased skin dose.

• 대한방사선기술학회지:방사선기술과학
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• 제41권5호
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• pp.405-411
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• 2018

We will provide basic data on the evaluation of patient dose in terms of DECT quality control by comparing the equipment-provided dose with the measured dose according to the configuration method of the X-ray generator by the manufacturer of the dual-energy CT unit. For computed tomography (CT) equipment, Discovery 750HD, Aquilion ONE GENESIS Edition, and Somatom Definition Flash were used. The $CTDI_{vol}$ value was measured by inserting the Unfors Xi ion chamber into a 32 cm PMMA acryl Phantom. The results of estimated $CTDI_{vol}$ DECT and measured $CTDI_{vol}$ showed that the dose difference between DECT 80 + 140 kVp of G company was at least 0.51% and -1.90% max, and measured $CTDI_{vol}$ was slightly lower (p<0.05). The difference of 80 + 140 kVp of S company was the minimum of 5.84% and the maximum of 7.52% (p<0.05). The measured $CTDI_{vol}$ was less than estimated $CTDI_{vol}$. The C company's 80 + 135 kVp showed a difference of at least 7.58% and a maximum of 13.58% (P<0.05), and all of measured $CTDI_{vol}$ was less. The linearity of exposure dose for all DECT equipment was very linearly reflected with $R^2$ being 0.97 or above, and the measured dose of the ionization chamber was less than the predicted dose of the monitor.

• 대한의용생체공학회:의공학회지
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• 제27권6호
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• pp.332-336
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• 2006

In this study, we have fabricated a fiber-optic radiation sensor using an organic scintillator for high energy electron beam therapy. The intensities of scintillating light from a fiber-optic radiation sensor are measured with different field size, electron beam energy and monitor unit of a clinical linear accelerator. To obtain percent depth dose(PDD), the amount of scintillating light is measured at different depth of polymethylmethacrylate(PMMA) phantom. Also the intensity of Cerenkov light is measured and characterized as a function of incident angle of electron beam and a subtraction method is investigated using a background optical fiber to remove a Cerenkov light.

• Nuclear Engineering and Technology
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• 제55권6호
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• pp.2018-2025
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• 2023

In our previous study, we proposed an integrated PG-PET-based imaging method to increase the prediction accuracy for patient dose distributions. The purpose of the present study is to experimentally validate the feasibility of the PG-PET system. Based on the detector geometry optimized in the previous study, we constructed a dual-head PG-PET system consisting of a 16 × 16 GAGG scintillator and KETEK SiPM arrays, BaSO₄ reflectors, and an 8 × 8 parallel-hole tungsten collimator. The performance of this system as equipped with a proof of principle, we measured the PG and positron emission (PE) distributions from a 3 × 6 × 10 cm³ PMMA phantom for a 45 MeV proton beam. The measured depth was about 17 mm and the expected depth was 16 mm in the computation simulation under the same conditions as the measurements. In the comparison result, we can find a 1 mm difference between computation simulation and measurement. In this study, our results show the feasibility of the PG-PET system for in-vivo range verification. However, further study should be followed with the consideration of the typical measurement conditions in the clinic application.

• 대한핵의학회지
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• 제35권2호
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• pp.100-112
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• 2001

목적: 본 연구의 목적은 NEMA 프로토콜에 따라서 GE $Advance^{TM}$ PET 시스템의 성능을 평가하고 그러한 시스템이 나타낼 수 있는 능력과 한계점을 명확히 이해하는데 있다. 대상 및 방법: 성능평가는 $^{18}FDG$ 선상선윈 및 점선원 그리고 NEMA 팬텀을 사용하여 횡축방향 공간분해능, 축방향 공간분해능, 산란분획, 민감도, 계수율손실, 계수율보정, 산란보정, 균일도보정, 감쇠보정을 대상으로 하였다. 횡축방향 공간분해능과 축방향 공간분해능, 산란분획에서는 선상선원 및 점선원을 사용하여 각각 NEMA 프로토콜에 따라 정해진 위치로 이동시키면서 측정하였고, 산란분획 및 나머지 성능평가 검사에서는 직경 20 cm의 PMMA 재질의 팬텀을 이용하여 측정하였다. 결과: 표준영상 획득 모드에서 시행한 본 성능평가의 결과를 고민감도 모드 및 고분해능 모드에 대하여 얻었다. 고민감도 모드에서 동경방향으로 측정된 횡축방향 공간분해능은 스캐너 시야중심에서 4.8 mm, 20 cm에서 7.03 mm로 감소했으며 축방향 공간분해능은 스캐너 시야중심에서 평균 3.98 mm, 20 cm에서 6.71 mm로 감소하였다. 산란분획은 고민감도 모드에서 평균 9.87%였고, 민감도 측정의 결과는 고민감도 모드, 시스템 전체에 대해서 참동시계수율 $225.8kcps/{\mu}Ci/cc$를 얻었고 계수율손실 측정은 50%의 불응시간을 가지는 방사능 농도가 $4.6{\mu}Ci/cc$였으며 이때의 계수율은 427 kcps였다. 계수율 보정의 오차는 고민감도 모드, $4.60{\mu}Ci/cc$에서 최소 1.49%, 최대 3.83%였고, 산란보정의 오차는 고민감도 모드에서 평균 -0.95%였으며 균일도보정 측정은 영상면들 간의 비균일도가 최소 -1.25%, 최대 1.74%였고 변이계수는 0.74%였다. 감쇠보정의 오차는 공기에서 5.68%, 물 0.04%, 테플론 -6.51%를 얻었다. 결론: NEMA 프로토콜에 근거하여 본 연구에서 실시한 표준 성능 평가 검사는 모두 제조사의 시험지침서에 부합하였다. 결론적으로, 이는 본 GE $Advance^{TM}$ PET 시스템이 임상에의 적용에 적합함을 보여주었다.