Your search keyword '"Bo-Wi Cheon"' showing total 11 results

1. Feasibility study of spent fuel internal tomography (SFIT) for partial defect detection within PWR spent nuclear fuel

Author

Hyung-Joo Choi, Hyojun Park, Bo-Wi Cheon, Hyun Joon Choi, Hakjae Lee, Yong Hyun Chung, and Chul Hee Min

Subjects

Safeguards, Non-proliferation, Spent nuclear fuel, Partial defect, Gamma emission tomography, Monte Carlo simulation, Nuclear engineering. Atomic power, TK9001-9401

Abstract

The International Atomic Energy Agency (IAEA) mandates safeguards to ensure non-proliferation of nuclear materials. Among inspection techniques used to detect partial defects within spent nuclear fuel (SNF), gamma emission tomography (GET) has been reported to be reliable for detection of partial defects on a pin-by-pin level. Conventional GET, however, is limited by low detection efficiency due to the high density of nuclear fuel rods and self-absorption. This paper proposes a new type of GET named Spent Fuel Internal Tomography (SFIT), which can acquire sinograms at the guide tube. The proposed device consists of the housing, shielding, C-shaped collimator, reflector, and gadolinium aluminum gallium garnet (GAGG) scintillator. For accurate attenuation correction, the source-distinguishable range of the SFIT device was determined using MC simulation to the region away from the proposed device to the second layer. For enhanced inspection accuracy, a proposed specific source-discrimination algorithm was applied. With this, the SFIT device successfully distinguished all source locations. The comparison of images of the existing and proposed inspection methods showed that the proposed method, having successfully distinguished all sources, afforded a 150 % inspection accuracy improvement.

Published

2024

2. Prompt gamma imaging system in particle therapy: a mini-review

Author

Bo-Wi Cheon and Chul Hee Min

Subjects

prompt gamma imaging, particle therapy, imaging system, in-vivo dose verification, real-time, Physics, QC1-999

Abstract

Accurate in-vivo verification of beam range and dose distribution is crucial for the safety and effectiveness of particle therapy. Prompt gamma (PG) imaging, as a method for real-time verification, has gained prominence in this area. Currently, several PG imaging systems are under development, including gamma electron vertex imaging (GEVI), the Compton camera, the slit camera, and the multi-array type collimator camera. However, challenges persist in dose prediction accuracy, largely due to patient positioning uncertainty and anatomical changes. Although each system demonstrates potential in verifying PG range, further improvements in detection efficiency, spatial resolution, background reduction, and integration into clinical workflows are essential.

Published

2024

3. Implementation of Visible monkey into general-purpose Monte Carlo codes: MCNP, PHITS, and Geant4

Author

Soo Min Lee, Chansoo Choi, Bangho Shin, Yumi Lee, Ji Won Choi, Bo-Wi Cheon, Chul Hee Min, Beom Sun Chung, Hyun Joon Choi, and Yeon Soo Yeom

Subjects

Monkey voxel phantom, Computational phantom, Organ/tissue dose, Monte Carlo simulation, Photon, Nuclear engineering. Atomic power, TK9001-9401

Abstract

Recently, a new monkey computational phantom, called Visible Monkey, was developed for non-ionizing radiation studies in animal research. In this study, we extended its applications to ionizing radiation studies by implementing the voxel model of the Visible Monkey into three general-purpose Monte Carlo (MC) codes: MCNP6, PHITS, and Geant4. The implementation work for MCNP and PHITS was conducted using the LATTICE, UNIVERSE, and FILL cards. The G4VNestedParameterisation class was used for Geant4. Then, organ dose coefficients (DCs) for idealized photon beams in the antero-posterior direction were calculated using the three codes and compared, showing excellent agreement (differences

Published

2023

4. Experiment of proof-of-principle on prompt gamma-positron emission tomography (PG-PET) system for in-vivo dose distribution verification in proton therapy

Author

Bo-Wi Cheon, Hyun Cheol Lee, Sei Hwan You, Hee Seo, Chul Hee Min, and Hyun Joon Choi

Subjects

Proton therapy, Prompt gamma, Positron emission tomography, In vivo dose verification, Experiment, Detector, Nuclear engineering. Atomic power, TK9001-9401

Abstract

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.

Published

2023

5. Experimental evaluation of fuel rod pattern analysis in fuel assembly using Yonsei single-photon emission computed tomography (YSECT)

Author

Hyung-joo Choi, Bo-Wi Cheon, Min Kyu Baek, Heejun Chung, Yong Hyun Chung, Sei Hwan You, Chul Hee Min, and Hyun Joon Choi

Subjects

Yonsei single-photon emission computed tomography (YSECT), Nuclear fuel assembly, Prototype, Fuel rod pattern analysis, Experiment, Nuclear engineering. Atomic power, TK9001-9401

Abstract

The purpose of this study was to verify the possibility of fuel rod pattern analysis in a fresh fuel assembly using the Yonsei single-photon emission computed tomography (YSECT) system. The YSECT system consisted of three main parts: four trapezoidal-shaped bismuth germanate scintillator-based 64-channel detectors, a semiconductor-based multi-channel data acquisition system, and a rotary stage. In order to assess the performance of the prototype YSECT, tomographic images were obtained for three representative fuel rod patterns in the 6 × 6 array using two representative image-reconstruction algorithms. The fuel-rod patterns were then assessed using an in-house fuel rod pattern analysis algorithm. In the experimental results, the single-directional projection images for those three fuel-rod patterns well discriminated each fuel-rod location, showing a Gaussian-peak-shaped projection for a single 10 mm-diameter fuel rod with 12.1 mm full-width at half maximum. Finally, we successfully verified the possibility of the fuel rod pattern analysis for all three patterns of fresh fuel rods with the tomographic images obtained by the rotational YSECT system.

Published

2022

6. Optimization of target, moderator, and collimator in the accelerator-based boron neutron capture therapy system: A Monte Carlo study

Author

Bo-Wi Cheon, Dohyeon Yoo, Hyojun Park, Hyun Cheol Lee, Wook-Geun Shin, Hyun Joon Choi, Bong Hwan Hong, Heejun Chung, and Chul Hee Min

Subjects

Boron Neutron Capture Therapy, TMC, Monte Carlo, MCNP, Optimization, Nuclear engineering. Atomic power, TK9001-9401

Abstract

The aim of this study was to optimize the target, moderator, and collimator (TMC) in a neutron beam generator for the accelerator-based BNCT (A-BNCT) system. The optimization employed the Monte Carlo Neutron and Photon (MCNP) simulation. The optimal geometry for the target was decided as the one with the highest neutron flux among nominates, which were called as angled, rib, and tube in this study. The moderator was optimized in terms of consisting material to produce appropriate neutron energy distribution for the treatment. The optimization of the collimator, which wrapped around the target, was carried out by deciding the material to effectively prevent the leakage radiations. As results, characteristic of the neutron beam from the optimized TMC was compared to the recommendation by the International Atomic Energy Agent (IAEA). The tube type target showed the highest neutron flux among nominates. The optimal material for the moderator and collimator were combination of Fluental (Al203+AlF3) with 60Ni filter and lead, respectively. The optimized TMC satisfied the IAEA recommendations such as the minimum production rate of epithermal neutrons from thermal neutrons: that was 2.5 times higher. The results can be used as source terms for shielding designs of treatment rooms.

Published

2021

7. TET2DICOM-GUI: Graphical User Interface Based TET2DICOM Program to Convert Tetrahedral-Mesh-Phantom to DICOM-RT Dataset

Author

Se Hyung Lee, Bo-Wi Cheon, Chul Hee Min, Haegin Han, Chan Hyeong Kim, Min Cheol Han, and Seonghoon Kim

Subjects

General Medicine

Published

2022

8. Development of light and radiation fields coincidence test toolkit for LINAC quality assurance

Author

Se Hyung Lee, Bo-Wi Cheon, Chul Hee Min, Chan Hyeong Kim, Seonghoon Kim, and Min Cheol Han

Subjects

General Physics and Astronomy

Published

2022

9. TOPAS-imaging: extensions to the TOPAS simulation toolkit for medical imaging systems

Author

Hoyeon Lee, Bo-Wi Cheon, Joseph W Feld, Kira Grogg, Joseph Perl, José A Ramos-Méndez, Bruce Faddegon, Chul Hee Min, Harald Paganetti, and Jan Schuemann

Subjects

Radiological and Ultrasound Technology, Radiology, Nuclear Medicine and imaging

Abstract

Objective. The TOol for PArticle Simulation (TOPAS) is a Geant4-based Monte Carlo software application that has been used for both research and clinical studies in medical physics. So far, most users of TOPAS have focused on radiotherapy-related studies, such as modeling radiation therapy delivery systems or patient dose calculation. Here, we present the first set of TOPAS extensions to make it easier for TOPAS users to model medical imaging systems. Approach. We used the extension system of TOPAS to implement pre-built, user-configurable geometry components such as detectors (e.g. flat-panel and multi-planar detectors) for various imaging modalities and pre-built, user-configurable scorers for medical imaging systems (e.g. digitizer chain). Main results. We developed a flexible set of extensions that can be adapted to solve research questions for a variety of imaging modalities. We then utilized these extensions to model specific examples of cone-beam CT (CBCT), positron emission tomography (PET), and prompt gamma (PG) systems. The first of these new geometry components, the FlatImager, was used to model example CBCT and PG systems. Detected signals were accumulated in each detector pixel to obtain the intensity of x-rays penetrating objects or prompt gammas from proton-nuclear interaction. The second of these new geometry components, the RingImager, was used to model an example PET system. Positron–electron annihilation signals were recorded in crystals of the RingImager and coincidences were detected. The simulated data were processed using corresponding post-processing algorithms for each modality and obtained results in good agreement with the expected true signals or experimental measurement. Significance. The newly developed extension is a first step to making it easier for TOPAS users to build and simulate medical imaging systems. Together with existing TOPAS tools, this extension can help integrate medical imaging systems with radiotherapy simulations for image-guided radiotherapy.

Published

2023

10. Radionuclide Identification Based on Energy-Weighted Algorithm and Machine Learning with Multi-Array Plastic Scintillator

Author

Hyun Cheol Lee, Bon Tack Koo, Ju Young Jeon, Bo-Wi Cheon, Do Hyeon Yoo, Heejun Chung, and Chul Hee Min

Subjects

History, Polymers and Plastics, Business and International Management, Industrial and Manufacturing Engineering

Published

2022

11. Development of a novel program for conversion from tetrahedral‐mesh‐based phantoms to DICOM dataset for radiation treatment planning: TET2DICOM

Author

Chul Hee Min, Se Hyung Lee, Jin Sung Kim, Min Cheol Han, Haegin Han, Chan Hyeong Kim, and Bo-Wi Cheon

Subjects

Computer science, tetrahedral‐mesh phantom, computer.software_genre, Imaging phantom, clinical software, DICOM, Software, voxelization, Voxel, Computer graphics (images), Technical Note, Humans, Radiology, Nuclear Medicine and imaging, Radiation treatment planning, Instrumentation, Sweden, Radiation, Phantoms, Imaging, business.industry, Radiotherapy Planning, Computer-Assisted, Distortion (optics), File format, Technical Notes, Tomography, X-Ray Computed, business, computer, CT, Volume (compression)

Abstract

Purpose Tetrahedral mesh (TM)-based computational human phantoms have recently been developed for evaluation of exposure dose with the merit of precisely representing human anatomy and the changing posture freely. However, conversion of recently developed TM phantoms to the Digital Imaging and Communications in Medicine (DICOM) file format, which can be utilized in the clinic, has not been attempted. The aim of this study was to develop a technique, called TET2DICOM, to convert the TM phantoms to DICOM datasets for accurate treatment planning. Materials and methods The TM phantoms were sampled in voxel form to generate the DICOM computed tomography images. The DICOM-radiotherapy structure was defined based on the contour data. To evaluate TET2DICOM, the shape distortion of the TM phantoms during the conversion process was assessed, and the converted DICOM dataset was implemented in a commercial treatment planning system (TPS). Results The volume difference between the TM phantoms and the converted DICOM dataset was evaluated as less than about 0.1% in each organ. Subsequently, the converted DICOM dataset was successfully implemented in MIM (MIM Software Inc., Cleveland, USA, version 6.5.6) and RayStation (RaySearch Laboratories, Stockholm, Sweden, version 5.0). Additionally, the various possibilities of clinical application of the program were confirmed using a deformed TM phantom in various postures. Conclusion In conclusion, the TM phantom, currently the most advanced computational phantom, can be implemented in a commercial TPS and this technique can enable various TM-based applications, such as evaluation of secondary cancer risk in radiotherapy.

Published

2021