5 results on '"Norikazu Arai"'
Search Results
2. First experience of 192Ir source stuck event during high-dose-rate brachytherapy in Japan
- Author
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Jun'ichi Kotoku, Shinobu Kumagai, Kenshiro Shiraishi, Hiroshi Oba, Daisuke Kon, Toshiya Saitoh, Takeshi Takata, Norikazu Arai, and Shigeru Furui
- Subjects
medicine.medical_specialty ,Event (computing) ,business.industry ,medicine.medical_treatment ,Treatment process ,Brachytherapy ,brachytherapy ,Treatment room ,Case Report ,monte carlo simulation ,High-Dose Rate Brachytherapy ,Emergency response ,Oncology ,medicine ,Medicine ,Radiology, Nuclear Medicine and imaging ,Medical physics ,Dose rate ,business ,medical event - Abstract
Purpose To share the experience of an iridium-192 (192Ir) source stuck event during high-dose-rate (HDR) brachytherapy for cervical cancer. Material and methods In 2014, we experienced the first source stuck event in Japan when treating cervical cancer with HDR brachytherapy. The cause of the event was a loose screw in the treatment device that interfered with the gear reeling the source. This event had minimal clinical effects on the patient and staff; however, after the event, we created a normal treatment process and an emergency process. In the emergency processes, each staff member is given an appropriate role. The dose rate distribution calculated by the new Monte Carlo simulation system was used as a reference to create the process. Results According to the calculated dose rate distribution, the dose rates inside the maze, near the treatment room door, and near the console room were ≅ 10-2 [cGy · h-1], 10-3 [cGy · h-1], and << 10-3 [cGy · h-1], respectively. Based on these findings, in the emergency process, the recorder was evacuated to the console room, and the rescuer waited inside the maze until the radiation source was recovered. This emergency response manual is currently a critical workflow once a year with vendors. Conclusions We reported our experience of the source stuck event. Details of the event and proposed emergency process will be helpful in managing a patient safety program for other HDR brachytherapy users.
- Published
- 2020
3. Fast skin dose estimation system for interventional radiology
- Author
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Shinobu Kumagai, Takenori Kobayashi, Shigeru Furui, Norikazu Arai, Masayoshi Yamamoto, Hideyuki Maejima, Takeshi Takata, Kenshiro Shiraishi, Jun'ichi Kotoku, and Hiroshi Kondo
- Subjects
Time Factors ,Computer science ,Health, Toxicology and Mutagenesis ,Monte Carlo method ,Radiation ,Radiology, Interventional ,Radiation Dosage ,Imaging phantom ,030218 nuclear medicine & medical imaging ,03 medical and health sciences ,0302 clinical medicine ,medicine ,Calibration ,Regular Paper ,Fluoroscopy ,Humans ,Radiology, Nuclear Medicine and imaging ,Computer Simulation ,MC-GPU ,Monte Carlo simulation ,Skin ,Dosimeter ,medicine.diagnostic_test ,Pixel ,business.industry ,Phantoms, Imaging ,Reproducibility of Results ,Interventional radiology ,Dose-Response Relationship, Radiation ,030220 oncology & carcinogenesis ,IR ,Nuclear medicine ,business ,radiation dose - Abstract
To minimise the radiation dermatitis related to interventional radiology (IR), rapid and accurate dose estimation has been sought for all procedures. We propose a technique for estimating the patient skin dose rapidly and accurately using Monte Carlo (MC) simulation with a graphical processing unit (GPU, GTX 1080; Nvidia Corp.). The skin dose distribution is simulated based on an individual patient’s computed tomography (CT) dataset for fluoroscopic conditions after the CT dataset has been segmented into air, water and bone based on pixel values. The skin is assumed to be one layer at the outer surface of the body. Fluoroscopic conditions are obtained from a log file of a fluoroscopic examination. Estimating the absorbed skin dose distribution requires calibration of the dose simulated by our system. For this purpose, a linear function was used to approximate the relation between the simulated dose and the measured dose using radiophotoluminescence (RPL) glass dosimeters in a water-equivalent phantom. Differences of maximum skin dose between our system and the Particle and Heavy Ion Transport code System (PHITS) were as high as 6.1%. The relative statistical error (2 σ) for the simulated dose obtained using our system was ≤3.5%. Using a GPU, the simulation on the chest CT dataset aiming at the heart was within 3.49 s on average: the GPU is 122 times faster than a CPU (Core i7–7700K; Intel Corp.). Our system (using the GPU, the log file, and the CT dataset) estimated the skin dose more rapidly and more accurately than conventional methods.
- Published
- 2017
4. First experience of 192Ir source stuck event during high-dose-rate brachytherapy in Japan.
- Author
-
Shinobu Kumagai, Norikazu Arai, Takeshi Takata, Daisuke Kon, Toshiya Saitoh, Hiroshi Oba, Shigeru Furui, Jun'ichi Kotoku, and Kenshiro Shiraishi
- Subjects
- *
HIGH dose rate brachytherapy , *RADIOISOTOPE brachytherapy , *MONTE Carlo method , *RADIATION sources , *CERVICAL cancer - Abstract
Purpose: To share the experience of an iridium-192 (192Ir) source stuck event during high-dose-rate (HDR) brachytherapy for cervical cancer. Material and methods: In 2014, we experienced the first source stuck event in Japan when treating cervical cancer with HDR brachytherapy. The cause of the event was a loose screw in the treatment device that interfered with the gear reeling the source. This event had minimal clinical effects on the patient and staff; however, after the event, we created a normal treatment process and an emergency process. In the emergency processes, each staff member is given an appropriate role. The dose rate distribution calculated by the new Monte Carlo simulation system was used as a reference to create the process. Results: According to the calculated dose rate distribution, the dose rates inside the maze, near the treatment room door, and near the console room were ≅ 10-2 [cGy · h-1], 10-3 [cGy · h-1], and << 10-3 [cGy · h-1], respectively. Based on these findings, in the emergency process, the recorder was evacuated to the console room, and the rescuer waited inside the maze until the radiation source was recovered. This emergency response manual is currently a critical workflow once a year with vendors. Conclusions: We reported our experience of the source stuck event. Details of the event and proposed emergency process will be helpful in managing a patient safety program for other HDR brachytherapy users. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
5. Design and fabrication of a metallic nanostamp using UV nanoimprinting and electroforming for replicating discrete track media with feature size of 35 nm.
- Author
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Jiseok Lim, Hyun-guk Hong, Jungjin Han, Eikhyun Cho, Young-joo Kim, Hiroshi Hatano, and Norikazu Arai
- Subjects
BACK up systems ,DATA warehousing ,INFORMATION retrieval research ,ELECTROFORMING ,ELECTROMETALLURGY - Abstract
The demand for high-density data-storage media is increasing, necessitating the development of novel magnetic data-storage technologies. Among the various types of storage media, discrete track media (DTM) is an emerging technology that is being used to overcome the limitations of conventional continuous magnetic data-storage technology, such as the superparamagnetic effect and medium noise. In this study, the authors propose a method of fabricating a metallic stamp for replicating DTM patterns using ultraviolet (UV) nanoimprinting and electroforming, which are inexpensive processes that can be used to fabricate nanostructures with high precision. First, a silicon nanomaster with a feature size of 35 nm and a pitch of 70 nm was designed and fabricated by electron-beam recording and inductively coupled plasma etching. The measured pitch of the silicon master was 71.6 nm. Then, a polymeric master with a full track of nanoline patterns was then replicated from the silicon nanomaster via UV nanoimprinting. To improve the releasing properties during UV nanoimprinting, the silicon nanomaster was coated with a self-assembled monolayer of fluoroctatrichlorosilane. The measured average pitch and height of the replicated polymer master were 71.5 and 61 nm, respectively. Then, a metallic nanostamp with a thickness of 300 lm and a diameter of 80mm was fabricated using electroforming. The metallic nanostamp was successfully fabricated, and its geometrical properties were measured and analyzed. The pitch and height of fabricated nickel stamp were 71.2 and 60.3 nm, respectively. [ABSTRACT FROM AUTHOR]
- Published
- 2013
- Full Text
- View/download PDF
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