Updated on 2025/11/18

写真a

 
KIDA Katsuhiro
 
Organization
Faculty of Health Sciences Associate Professor
Position
Associate Professor
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Degree

  • 博士(保健学) ( 2012.3   岡山大学 )

Education

  • Okayama University   大学院保健学研究科   博士後期課程保健学専攻放射線技術科学分野

    2007.4 - 2012.3

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    Country: Japan

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  • Okayama University   大学院保健学研究科   博士前期課程保健学専攻放射線技術科学分野

    2005.4 - 2007.3

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    Country: Japan

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  • Okayama University   医療技術短期大学部  

    1992.4 - 1995.3

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    Country: Japan

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Research History

  • Okayama University   Graduate School of Health Sciences   Associate Professor

    2020.10

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    Country:Japan

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  • Japanese Red Cross Okayama Hospital   中央放射線部

    1995.4 - 2020.9

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    Country:Japan

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Papers

  • 超音波診断装置を用いた第1趾爪甲の荷重による広がりの定量的検討 Reviewed

    石川 静香, 齋藤 誠二, 木田 勝博, 長尾 洋, 五福 明夫, 森本 美智子

    人間工学   61 ( 1 )   43 - 50   2025.2

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    Language:Japanese   Publisher:(一社)日本人間工学会  

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  • Investigating the Effects of Reconstruction Conditions on Image Quality and Radiomic Analysis in Photon-counting Computed Tomography. Reviewed International journal

    Miyu Ohata, Ryohei Fukui, Yusuke Morimitsu, Daichi Kobayashi, Takatsugu Yamauchi, Noriaki Akagi, Mitsugi Honda, Aiko Hayashi, Koshi Hasegawa, Katsuhiro Kida, Sachiko Goto, Takao Hiraki

    Journal of medical physics   50 ( 1 )   100 - 107   2025

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    Language:English   Publishing type:Research paper (scientific journal)  

    INTRODUCTION: Photon-counting computed tomography (CT) is equipped with an adaptive iterative reconstruction method called quantum iterative reconstruction (QIR), which allows the intensity to be changed during image reconstruction. It is known that the reconstruction conditions of CT images affect the analysis results when performing radiomic analysis. The aim of this study is to investigate the effect of QIR intensity on image quality and radiomic analysis of renal cell carcinoma (RCC). MATERIALS AND METHODS: The QIR intensities were selected as off, 2 and 4. The image quality evaluation items considered were task-based transfer function (TTF), noise power spectrum (NPS), and low-contrast object specific contrast-to-noise ratio (CNRLO). The influence on radiomic analysis was assessed using the discrimination accuracy of clear cell RCC. RESULTS: For image quality evaluation, TTF and NPS values were lower and CNRLO values were higher with increasing QIR intensity; for radiomic analysis, sensitivity, specificity, and accuracy were higher with increasing QIR intensity. Principal component analysis and receiver operating characteristics analysis also showed higher values with increasing QIR intensity. CONCLUSION: It was confirmed that the intensity of the QIR intensity affects both the image quality and the radiomic analysis.

    DOI: 10.4103/jmp.jmp_114_24

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  • Effect of segmentation dimension on radiomics analysis for MGMT promoter methylation status in gliomas Reviewed

    Ryohei Fukui, Masataka Onishi, Koshi Hasegawa, Miyu Ohata, Katsuhiro Kida, Sachiko Goto

    Aktualności Neurologiczne   2024.7

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    Publishing type:Research paper (scientific journal)  

    DOI: 10.15557/AN.2024.0002

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  • Native myocardial T1 mapping using inversion recovery T1-weighted turbo field echo sequence. Reviewed

    Katsuhiro Kida, Takamasa Kurosaki, Ryohei Fukui, Ryutaro Matsuura, Sachiko Goto

    Radiological physics and technology   17 ( 2 )   425 - 432   2024.6

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    Authorship:Lead author, Corresponding author   Language:English   Publishing type:Research paper (scientific journal)  

    This study proposes the use of the inversion recovery T1-weighted turbo field echo (IR-T1TFE) sequence for myocardial T1 mapping and compares the results obtained with those of the modified Look-Locker inversion recovery (MOLLI) method for accuracy, precision, and reproducibility. A phantom containing seven vials with different T1 values was imaged, thereby comparing the T1 measurements between the inversion recovery spin-echo (IR-SE) technique, MOLLI, and the IR-T1TFE. The accuracy, precision, and reproducibility of the T1-mapping sequences were analyzed in a phantom study. Fifteen healthy subjects were recruited for the in vivo comparison of native myocardial T1 mapping using MOLLI and IR-T1TFE sequences. After myocardium segmentation, the T1 value of the entire myocardium was calculated. In the phantom study, excellent accuracy was achieved using IR-T1TFE for all T1 ranges. MOLLI displayed lower accuracy than IR-T1TFE (p =0.016), substantially underestimating T1 at large T1 values (> 1000 ms). In the in vivo study, the first mean myocardial T1 values ± SD using MOLLI and IR-T1TFE were 1306 ± 70 ms and 1484 ± 28 ms, respectively, and the second were 1297 ± 68 ms and 1474 ± 43 ms, respectively. The native myocardial T1 obtained with MOLLI was lower than that of IR-T1TFE (p < 0.001). The reproducibility of native myocardial T1 mapping within the same sequence was not statistically significant (p = 0.11). This study demonstrates the utility and validity of myocardial T1 mapping using IR-T1TFE, which is a common sequence. This method was found to have high accuracy and reproducibility.

    DOI: 10.1007/s12194-024-00795-w

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  • Assessment of a New Elbow Joint Positioning Method Using Area Detector Computed Tomography. Reviewed

    Takuya Akagawa, Ryohei Fukui, Katsuhiro Kida, Ryutaro Matsuura, Makoto Shimada, Mitsuhiro Kinoshita, Yoko Akagawa, Sachiko Goto

    Acta medica Okayama   78 ( 3 )   215 - 225   2024.6

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    Language:English   Publishing type:Research paper (scientific journal)  

    We propose a sitting position that achieves both high image quality and a reduced radiation dose in elbow joint imaging by area detector computed tomography (ADCT), and we compared it with the 'superman' and supine positions. The volumetric CT dose index (CTDIvol) for the sitting, superman, and supine positions were 2.7, 8.0, and 20.0 mGy and the dose length products (DLPs) were 43.4, 204.7, and 584.8 mGy • cm, respectively. In the task-based transfer function (TTF), the highest value was obtained for the sitting position in both bone and soft tissue images. The noise power spectrum (NPS) of bone images showed that the superman position had the lowest value up to approx. 1.1 cycles/mm or lower, whereas the sitting position had the lowest value when the NPS was greater than approx. 1.1 cycles/mm. The overall image quality in an observer study resulted in the following median Likert scores for Readers 1 and 2: 5.0 and 5.0 for the sitting position, 4.0 and 3.5 for the superman position, and 4.0 and 2.0 for the supine position. These results indicate that our proposed sitting position with ADCT of the elbow joint can provide superior image quality and allow lower radiation doses compared to the superman and supine positions.

    DOI: 10.18926/AMO/67196

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  • Proposal for diagnosis using FLAIR image aimed for pediatric MELAS with recurrent stroke-like episodes on MRI system cannot take ASL imaging Reviewed

    Makoto Shimada, Tae Ikeda, Ryohei Fukui, Katsuhiro Kida, Ryutaro Matsuura, Takuya Akagawa, Sachiko Goto

    Egyptian Pediatric Association Gazette   71 ( 1 )   2023.11

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    Publishing type:Research paper (scientific journal)   Publisher:Springer Science and Business Media LLC  

    Abstract

    Background

    Arterial spin-labeling (ASL) imaging is currently the most useful method for diagnosing mitochondrial encephalomyopathy, lactic acidosis, and stroke-like attack syndrome (MELAS). However, ASL is often an optional feature of standard MRI systems. Therefore, not all MRI systems can perform ASL imaging. In contrast, fluid-attenuated inversion recovery (FLAIR) imaging is one of the common sequences in brain MRI because FLAIR imaging can be performed regardless of the specifications of the equipment. This study aimed to compare the diagnostic performance of quantitative analysis of signal intensity obtained from fluid-attenuated inversion recovery (FLAIR) images with ASL images for MELAS with recurrent stroke-like episodes (SLEs). A total of 68 cases with normal magnetic resonance imaging findings and 25 cases diagnosed MELAS with recurrent SLEs were included. We evaluated the frontal lobe and cuneus as target areas and compared the regional cerebral blood flow (rCBF) values obtained from ASL images with the normalized signal intensity (nSI) obtained from FLAIR images.

    Results

    The sensitivity and specificity for diagnosing MELAS from linear discriminant analysis (LDA) obtained from the rCBF values were 0.84 and 0.941, respectively, and those of nSI were 0.8 and 0.897, respectively. The area under the ROC curves (AUC) calculated from the receiver operating characteristic (ROC) curve analysis using rCBF values and nSI were 0.889 and 0.804, respectively.

    Conclusion

    Quantitative analysis using the signal intensity of the FLAIR image could have a diagnostic performance equivalent to that of rCBF values obtained from ASL images.

    DOI: 10.1186/s43054-023-00232-4

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    Other Link: https://link.springer.com/article/10.1186/s43054-023-00232-4/fulltext.html

  • 3D phase-sensitive inversion recovery sequence for intracranial vertebrobasilar artery dissection. Reviewed International journal

    Takuya Enoki, Katsuhiro Kida, Wataru Jomoto, Yusuke Kawanaka, Manabu Shirakawa, Masataka Miyama, Noriko Kotoura, Sachiko Goto

    Journal of clinical neuroscience : official journal of the Neurosurgical Society of Australasia   118   52 - 57   2023.10

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    Authorship:Corresponding author   Language:English   Publishing type:Research paper (scientific journal)  

    BACKGROUND: T1-weighted 3D turbo spin echo (T1W-3D-TSE) sequences with variable refocusing flip angle are commonly used to diagnose intracranial vertebrobasilar artery dissection (iVAD). However, magnetic susceptibility artifacts of the cavernous sinus may cause loss of the basilar and vertebral arteries. This study investigated the effectiveness of a 3D phase-sensitive inversion recovery (3D-PSIR) sequence in reducing magnetic susceptibility artifacts in the cavernous sinus, and its imaging findings for iVAD. METHODS: Twelve volunteers and eleven patients with iVAD were included. Magnetic resonance imaging (MRI) was performed using a 3.0-T MRI system. 3D-PSIR and T1W-3D-TSE sequences were used. Vessel wall defects and contrast-to-noise ratio (CNR) were evaluated. The MRI findings were visually evaluated. RESULTS: In the 3D-PSIR images, one volunteer (8 %) had vessel wall defects, and five (42 %) had vessel wall defects (p = 0.046) in the T1W-3D-TSE images. CNR was higher in 3D-PSIR images for vessel wall-to-lumen, whereas it was higher in T1W-3D-TSE images for vessel wall-to-CSF (p < 0.001). Visual evaluation revealed similar MRI findings between the two sequences. CONCLUSIONS: The 3D-PSIR sequence may be able to improve the vessel wall defects and achieve MRI findings comparable to those of the T1W-3D-TSE sequence in iVAD. The 3D-PSIR sequence can be a useful tool for the imaging-based diagnosis of iVAD.

    DOI: 10.1016/j.jocn.2023.10.008

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  • Influence of Two-Dimensional and Three-Dimensional Acquisitions of Radiomic Features for Prediction Accuracy Reviewed

    Ryohei Fukui, Ryutarou Matsuura, Katsuhiro Kida, Sachiko Goto

    Progress in Medical Physics   34 ( 3 )   23 - 32   2023.9

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    Publishing type:Research paper (scientific journal)   Publisher:Korean Society of Medical Physics  

    DOI: 10.14316/pmp.2023.34.3.23

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  • Toenail Plate Size Measurement Through the Water-bath Method Using an Ultrasound System Reviewed

    ISHIKAWA Shizuka, SAITO Seiji, KIDA Katsuhiro, NAGAO Yoh, SASAKI Shinsuke

    The Japanese Journal of Ergonomics   59 ( 4 )   159 - 167   2023.8

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    Language:Japanese   Publisher:Japan Human Factors and Ergonomics Society  

    Diagnosis and assessment of nail lesions require an understanding of normal anatomical structures and information on their size. However, accurate measurement of the toenail plate on the nail bed has not been reported. This study investigated the usefulness and validity of a method of drawing and measuring the toenail plate through the water-bath method using an ultrasound system. The ultrasound images of the gel and water-bath methods of participants without nail lesions were compared. The thickness of the toenail plate was measured over time in the water. In addition, the thickness, height, width, and nail height index of the toenail plate of participants in their 20s and 40+ age groups were compared. The results showed that the water-bath method clearly depicted the toenail plate without artifacts. The thickness of the immersed toenail plate remained unchanged at 0 mm, and no significant difference was observed. Furthermore, significant differences were observed in the thickness, height, and nail height index of the toenail plate of participants in their 20s and 40+ age groups. These results demonstrate that this method can clearly image the toenail structure, and measure and evaluate the toenail plate.

    DOI: 10.5100/jje.59.159

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  • 3D phase-sensitive inversion recoveryを多発性硬化症に応用するための基礎的検討(Fundamental study for application of 3D phase-sensitive inversion recovery sequence to multiple sclerosis) Reviewed

    榎 卓也, 城本 航, 木田 勝博, 後藤 佐知子, 琴浦 規子

    JART: 日本診療放射線技師会誌   70 ( 6 )   580 - 587   2023.5

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  • Effect of Bead Device Diameter on Z-Resolution Measurement in Tomosynthesis Images: A Simulation Study Reviewed

    Ryohei Fukui, Miho Numata, Saki Nishioka, Ryutarou Matsuura, Katsuhiro Kida, Sachiko Goto

    Progress in Medical Physics   33 ( 4 )   1 - 9   2022.12

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    Language:English   Publishing type:Research paper (scientific journal)  

    DOI: 10.14316/pmp.2022.33.4.63

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  • Non-electrocardiogram-gated and Non-contrast-enhanced Magnetic Resonance Angiography of the Lower Limb Arteries Using Three-dimensional Multishot T1-weighted Fast-field Echo-Echo Planar Imaging Reviewed

    Komaki Shinsuke, Kida Katsuhiro, Hayashi Yukako, Shouda Takashi, Tabuchi Akihiko

    Japanese Journal of Radiological Technology   78 ( 4 )   333 - 341   2022

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    Authorship:Corresponding author   Language:Japanese   Publisher:Japanese Society of Radiological Technology  

    DOI: 10.6009/jjrt.2022-1239

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  • Effect of the Number of Projected Images on the Noise Characteristics in Tomosynthesis Imaging Reviewed International coauthorship International journal

    Ryohei Fukui, Ryutaro Matsuura, Katsuhiro Kida, Sachiko Goto

    Progress in Medical Physics   32 ( 2 )   50 - 58   2021.6

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    Publishing type:Research paper (scientific journal)   Publisher:Korean Society of Medical Physics  

    DOI: 10.14316/pmp.2021.32.2.50

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  • 進行性核上性麻痺の各臨床病型における特徴,各種検査所見およびその予後

    武久康, 遠部佳寿美, 渡邉竜也, 安藤研介, 河崎さおり, 戸田逸美, 西本めぐみ, 木田勝博, 都能和俊, 秋友信男, 梶谷努, 林英博

    岡山赤十字病院医学雑誌   26   2015

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  • High spatial resolution MRA of renal arteries using contrast behavior between fat and water during transient phase before reaching a steady state Reviewed

    Katsuhiro Kida, Sachiko Goto, Yoshiharu Azuma

    European Journal of Radiology   81 ( 5 )   846 - 850   2012.5

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    Authorship:Lead author   Language:English   Publishing type:Research paper (scientific journal)   Publisher:Elsevier BV  

    DOI: 10.1016/j.ejrad.2011.02.031

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  • 頭部MRIのT1強調画像における各種Contrast to Noise Ratio (CNR) 算出法の比較 Reviewed

    木田勝博, 後藤佐知子, 東義晴, 梶谷努

    日本放射線技師会雑誌   59 ( 3 )   313 - 318   2012.3

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  • 3.0-T MRIにおける拡散強調像の評価

    木田勝博, 後藤佐知子, 黒崎貴雅, 梶谷努, 東義晴

    岡山赤十字病院医学雑誌   23 ( 1 )   49 - 54   2012

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    Authorship:Lead author   Language:Japanese   Publishing type:Research paper (bulletin of university, research institution)  

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  • 頸部MRI脂肪抑制T1強調画像における磁化率アーチファクト軽減補助具(Sat-Pad)の作製

    木田 勝博, 後藤 佐知子, 梶谷 努, 東 義晴

    岡山赤十字病院医学雑誌   22   27 - 30   2011.11

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    Authorship:Lead author   Language:Japanese   Publishing type:Research paper (bulletin of university, research institution)   Publisher:岡山赤十字病院医学雑誌編集委員会  

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Books

  • MR画像検査学

    高津, 安男, 小野, 敦(6高速イメージング,10撮像技術④ 造影検査,MRCP)

    メジカルビュー社  2023.3  ( ISBN:9784758320955

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    Total pages:xii, 323p   Responsible for pages:100-117, 189-197   Language:Japanese

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Presentations

  • 自由呼吸下3D radial Dixon look- locker シーケンスを用いた水・脂肪分離 T1map と PDFFmap の同時取得の検討

    守屋和典, 福倉良彦, 上田優, 木田勝博, 後藤佐知子, 谷忠司, 柴田成

    日本放射線技術学会 第81回総会学術大会  2025.4.11 

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    Event date: 2025.4.10 - 2025.4.13

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  • Timing is everything! Dance of hydrogen atoms and MR image generation Invited

    Katsuhiro Kida

    2025.3.1 

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    Event date: 2025.3.1

    Language:Japanese   Presentation type:Public lecture, seminar, tutorial, course, or other speech  

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  • Prediction of fat suppression failure and water suppression areas in the CHESS method using short time imaging B0 map

    Kazunori Moriya, Katsuhiro Kida, Yuki Miyashima, Shigeru Shibata, Tadashi Tani, Yuki Nakamitsu, Sachiko Goto, Koji Yoshida

    The 52nd Annual Meeting of the Japanese Society for Magnetic Resonance in Medicine (JSMRM2024)  2024.9.22 

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    Event date: 2024.9.20 - 2024.9.22

    Language:Japanese   Presentation type:Oral presentation (general)  

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  • Validation of T1 mapping using 6-point 3D radial Look-Locker: A phantom study

    Kazunori Moriya, Yoshihiko Fukukura, Katsuhiro Kida, Sachiko Goto, Yu Ueda, Kota Amo, Shigeru Shibata, Koji Yoshida, Tsutomu Tamada

    The 51st Annual Meeting of the Japanese Society for Magnetic Resonance in Medicine  2023.9.23 

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    Event date: 2023.9.22 - 2023.9.24

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  • 高吸収体がトモシンセシステム画像ノイズ測定に与える影響

    福井亮平, 太田雄大, 沼田美保, 谷口菜摘子, 西岡早紀, 松浦龍太郎, 木田勝博, 後藤佐知子, 本田貢, 平木隆夫

    第17回 中四国放射線医療技術フォーラム CSFRT2021  2021.12.18 

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    Event date: 2021.12.18 - 2022.1.19

    Language:Japanese   Presentation type:Oral presentation (general)  

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  • Break the Common Sense! How the GraSE MRCP was created. Invited

    Katsuhiro KIDA

    Road to Gyro 2nd  2021.11.25 

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    Event date: 2021.11.25 - 2021.11.30

    Language:Japanese   Presentation type:Public lecture, seminar, tutorial, course, or other speech  

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  • Start with the basics and fundamentals -SE and EPI- Invited

    Katsuhiro Kida

    2021.6.20 

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    Event date: 2021.6.20

    Language:Japanese   Presentation type:Oral presentation (invited, special)  

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  • 多発性硬化症患者の脳高次機能障害と脳血流-SPECTの検討

    武久 康, 川口 洋子, 鶴川 春佳, 守本 佐保, 木田 勝博, 都能 和俊, 梶谷 努, 林 英博

    神経免疫学  2020.10  日本神経免疫学会

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    Event date: 2020.10

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  • Compressed Sensing 併用 3D IR-T1TFE 法とMOLLI法による心筋の T1 Mapping の測定精度の比較

    徐海人, 木田勝博, 後藤佐知子

    第76回日本放射線技術学会総会学術大会  2020.4.9 

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    Event date: 2020.4.9 - 2020.4.12

    Language:Japanese   Presentation type:Oral presentation (general)  

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  • 多発性硬化症患者の脳血流SPECTと認知機能障害について

    武久 康, 川口 洋子, 鶴川 春佳, 守本 佐保, 小川 さおり, 木田 勝博, 都能 和俊, 梶谷 努, 林 英博, 阿部 康二

    脳循環代謝  2019.11  (一社)日本脳循環代謝学会

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    Event date: 2019.11

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  • Three-Dimensional Time-of-Flight Magnetic Resonance Angiography Using Dual Echo for Ophthalmic Artery

    Takamasa Kurosaki, Katsuhiro Kida

    The 75th Annual Meeting of the Japanese Society of Radiological Technology (JSRT)  2019.4.14 

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    Event date: 2019.4.11 - 2019.4.14

    Language:English   Presentation type:Oral presentation (general)  

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  • Inversion Recovery T1-weighted Turbo Field-echo法を用いた心筋の3D T1 Mapping ー視認性の改善ー

    小野翔太郎, 木田勝博, 稲本英樹, 寺島正浩, 後藤佐知子, 東義晴

    日本放射線技術学会 第75回総会学術大会  2019.4.12 

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    Event date: 2019.4.11 - 2019.4.14

    Language:Japanese   Presentation type:Oral presentation (general)  

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  • Brief Breath-Holding for Increasing the Number of Slices in Myocardial Multi-slice T1 Mapping

    Katsuhiro Kida, Shotaro Ono, Sachiko Goto, Hideki Inamoto, Tsutomu Kajitani

    Proceedings of The 75th Annual Meeting of the Japanese Society of Radiological Technology (JSRT)  2019.4 

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    Event date: 2019.4

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  • Myocardial Multi-slice T1 Mapping Using Inversion Recovery T1 Turbo Field Echo (IR-T1TFE) Sequence

    S. Ono, K. Kida, H. Inamoto, M. Terashima, S. Goto, Y. Azuma

    ECR 2019, 25th European Congress of Radiology  2019.2 

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    Event date: 2019.2.27 - 2019.3.3

    Language:English   Presentation type:Oral presentation (general)  

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  • 大動脈血管壁評価を目的とした3D-Black Blood imaging Protocolの最適化

    後藤優治, 古牧伸介, 木田勝博, 青木翔太郎, 宮井将宏, 田淵昭彦

    中四国放射線医療技術フォーラムプログラム抄録集  2019 

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    Event date: 2019

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Awards

  • 2025 Chugoku/Shikoku Branch of the Radiological Technology Society of Japan Award for Distinguished Paper

    2025.7   Native myocardial T1 mapping using inversion recovery T1-weighted turbo field echo sequence

    Katsuhiro Kida, Takamasa Kurosaki, Ryohei Fukui, Ryutaro Matsuura, Sachiko Goto

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  • Technology Encouragement Award, Field of Photography (MR)

    2025.4   Japanese Society of Radiological Technology   Native myocardial T1 mapping using inversion recovery T1-weighted turbo field echo sequence

    Katsuhiro Kida, Takamasa Kurosaki, Ryohei Fukui, Ryutaro Matsuura, Sachiko Goto

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  • John A. Koveleski Award

    2017.3   SMRT 26th Annual Meeting  

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  • Gold Award

    2016.9   フィリップスMRIユーザーズミーティング全国大会Gyro Cup 2016  

    Katsuhiro Kida

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  • SMRT First Place Research Focus Award

    2013.4   SMRT 22nd Annual Meeting  

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  • 1st Place Poster Award in the category of Research Focus

    2012.5   SMRT 21st Annual Meeting  

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Class subject in charge

  • Health Care System and Law (2025academic year) Fourth semester  - 月3~4,木5~6

  • Equipment Engineering for Medical Imaging (2025academic year) 1st semester  - 金3~4

  • Seminar in Medical Imaging (2025academic year) Late  - 水7

  • Topics in Medical Imaging (2025academic year) Prophase  - 水7

  • Graduation Thesis in Radiological Technology (2025academic year) 1-3 semesters  - その他

  • Risk Management (2025academic year) Late  - 木7

  • Experiment of Medical Image Informatics (2025academic year) 1st semester  - 水1~6

  • Basic Pathophysiology (2025academic year) 3rd and 4th semester  - 金3~4

  • Practical Clinical Radiology Exercise (2025academic year) Second semester  - 金3~4

  • Human Macroscopic Anatomy of Radiology (2025academic year) 1st semester  - 月1~2

  • Clinical Practice (Special) (2025academic year) Fourth semester  - 月5~7,水5~7

  • Special Exercise in Clinical Medicine (2025academic year) Fourth semester  - 月5~7,水5~7

  • Practice in Clincal RadiologyI (2025academic year) 3rd and 4th semester  - [第3学期]火1~8,金1~8, [第4学期]火1~8,水1~8

  • Practice in Clincal RadiologyⅡ (2025academic year) 1-3 semesters  - その他

  • Practice in Clincal RadiologyⅡ (2025academic year) 1-3 semesters  - その他

  • Clinical Skills Practice (2025academic year) 1st and 2nd semester  - [第1学期]月7~8,火7~8,木7~8,金7~8, [第2学期]金5~7

  • Radiographic Technology I (2025academic year) Second semester  - 木1~2

  • Radiographic Technology II (2025academic year) Fourth semester  - 水3~4

  • Radiographic Technology III (2025academic year) 1st semester  - 木3~4

  • Radiographic Technology Practices (2025academic year) 1st semester  - 月6,火6,木6,金6

  • Radiographic Technology (2025academic year) 1st semester  - 火1~2

  • Ultrasonography (2025academic year) Second semester  - 火7~8

  • Magnetic Resonance Imaging (2025academic year) Second semester  - 水1~2

  • Health Care System and Law (2024academic year) Fourth semester  - 月1~2,金1~2

  • Equipment Engineering for Medical Imaging (2024academic year) 1st semester  - 金4~5

  • Seminar in Medical Imaging (2024academic year) Late  - 水7

  • Topics in Medical Imaging (2024academic year) Prophase  - 水7

  • Graduation Thesis in Radiological Technology (2024academic year) 1-3 semesters  - その他

  • Risk Management (2024academic year) Late  - 木7

  • Experiment of Medical Image Informatics (2024academic year) Second semester  - 月1~6

  • Basic Pathophysiology (2024academic year) 3rd and 4th semester  - 金3~4

  • Practical Clinical Radiology Exercise (2024academic year) Second semester  - 金4~5

  • Human Macroscopic Anatomy of Radiology (2024academic year) 1st semester  - 月2~3

  • Clinical Practice (Special) (2024academic year) Fourth semester  - 月4~6,水4~6

  • Practice in Clincal RadiologyI (2024academic year) 3rd and 4th semester  - [第3学期]火3~6,金3~6, [第4学期]火3~6,水3~6

  • Practice in Clincal RadiologyⅡ (2024academic year) 1-3 semesters  - その他

  • Clinical Skills Practice (2024academic year) 1st and 2nd semester  - 金6~8

  • Clinical Skills Exercise (2024academic year) 1st semester  - 金6~8

  • Radiographic Technology I (2024academic year) Second semester  - 木1~2

  • Radiographic Technology II (2024academic year) Fourth semester  - 水4~5

  • Radiographic Technology III (2024academic year) 1st semester  - 木6~7

  • Radiographic Technology Practices (2024academic year) 3rd and 4th semester  - [第3学期]火1~2,金1~2, [第4学期]火1~2,水1~2

  • Radiographic Technology (2024academic year) 1st semester  - 火2~3

  • Ultrasonography (2024academic year) Second semester  - 火7~8

  • Magnetic Resonance Imaging (2024academic year) Second semester  - 水1~2

  • Exercise of Team Medical Activities (2023academic year) 1st and 2nd semester  - その他

  • Health Care System and Law (2023academic year) Fourth semester  - 月2~3,木2~3

  • Equipment Engineering for Medical Imaging (2023academic year) Second semester  - 金5~6

  • Seminar in Medical Imaging (2023academic year) Late  - 水7

  • Topics in Medical Imaging (2023academic year) Prophase  - 水7

  • Graduation Thesis in Radiological Technology (2023academic year) 1-3 semesters  - その他

  • Risk Management (2023academic year) Late  - 木7

  • Experiment of Medical Image Informatics (2023academic year) Second semester  - 月1~6

  • Basic Pathophysiology (2023academic year) 3rd and 4th semester  - 金3~4

  • Basic Pathophysiology (2023academic year) 3rd and 4th semester  - 金3~4

  • Basic Pathophysiology (2023academic year) 3rd and 4th semester  - 金3~4

  • Human Macroscopic Anatomy of Radiology (2023academic year) 1st semester  - 木1~2

  • Human Macroscopic Anatomy (2023academic year) 1st semester  - 木1~2

  • Clinical Practice (Special) (2023academic year) Fourth semester  - 月4~6,水4~6

  • Practice in Clincal RadiologyⅡ (2023academic year) 1-3 semesters  - その他

  • Practice in Clincal RadiologyI (2023academic year) special  - その他

  • Clinical Skills Exercise (2023academic year) Second semester  - 金7~8

  • Radiographic Technology Practices (2023academic year) 3rd and 4th semester  - [第3学期]火1~4,金1~4, [第4学期]火1~4,水1~4

  • Radiographic Technology (2023academic year) Third semester  - 月1~2

  • Radiographic Technology I (2023academic year) Second semester  - 木1~2

  • Radiographic Technology II (2023academic year) Fourth semester  - 水4~5

  • Radiographic Technology III (2023academic year) Second semester  - 木6~7

  • Ultrasonography (2023academic year) Second semester  - 火7~8

  • Magnetic Resonance Imaging (2023academic year) Third semester  - 水5~6

  • Health Care System and Law (2022academic year) Fourth semester  - 月2~3,木2~3

  • Equipment Engineering for Medical Imaging (2022academic year) Second semester  - 金5~6

  • Seminar in Medical Imaging (2022academic year) Late  - 水7

  • Graduation Thesis in Radiological Technology (2022academic year) 1-3 semesters  - その他

  • Basic Pathophysiology (2022academic year) 3rd and 4th semester  - 金3~4

  • Basic Pathophysiology (2022academic year) 3rd and 4th semester  - 金3~4

  • Basic Pathophysiology (2022academic year) 3rd and 4th semester  - 金3~4

  • Human Macroscopic Anatomy (2022academic year) 1st semester  - 木1~2

  • Clinical Practice (Special) (2022academic year) Fourth semester  - 月4~6,水4~6

  • Practice in Clincal RadiologyI (2022academic year) special  - その他

  • Simulation-based Clinical-Skills Examination (2022academic year) Second semester  - 金7~8

  • Radiographic Technology Practices (2022academic year) 3rd and 4th semester  - [第3学期]火1~4,金1~4, [第4学期]火1~4,水1~4

  • Radiographic Technology (2022academic year) Third semester  - 月1~2

  • Radiographic Technology I (2022academic year) Second semester  - 木1~2

  • Radiographic Technology II (2022academic year) Fourth semester  - 水4~5

  • Radiographic Technology III (2022academic year) Second semester  - 金3~4

  • Ultrasonography (2022academic year) Second semester  - 火7~8

  • Magnetic Resonance Imaging (2022academic year) Third semester  - 水7~8

  • Health Care System and Law (2021academic year) Fourth semester  - 月2~3,木2~3

  • Graduation Thesis in Radiological Technology (2021academic year) 1-3 semesters  - その他

  • Experiment of Radiation Equipment Engineering (2021academic year) 3rd and 4th semester  - [第3学期]火5~8,金5~8, [第4学期]火5~8,水5~8

  • Human Macroscopic Anatomy (2021academic year) 1st semester  - 木1~2

  • Clinical Practice (Special) (2021academic year) Fourth semester  - 月4~6,水4~6

  • Practice in Clincal RadiologyⅡ (2021academic year) 1-3 semesters  - その他

  • Practice in Clincal RadiologyI (2021academic year) special  - その他

  • Simulation-based Clinical-Skills Examination (2021academic year) Summer concentration  - その他

  • Radiographic Technology Practices (2021academic year) 3rd and 4th semester  - [第3学期]火1~4,金1~4, [第4学期]火1~4,水1~4

  • Radiographic Technology (2021academic year) Third semester  - 月1~2

  • Radiographic Technology I (2021academic year) Second semester  - 木1~2

  • Radiographic Technology II (2021academic year) Fourth semester  - 水4~5

  • Radiographic Technology III (2021academic year) Second semester  - 金3~4

  • Ultrasonography (2021academic year) Second semester  - 火7~8

  • Magnetic Resonance Imaging (2021academic year) Third semester  - 水7~8

  • Health Care System and Law (2020academic year) Fourth semester  - 月2,月3,木2,木3

  • Radiographic Technology (2020academic year) Third semester  - 月1,月2

  • Radiographic Technology II (2020academic year) Fourth semester  - 水4,水5

  • Magnetic Resonance Imaging (2020academic year) Third semester  - 水7,水8

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Academic Activities

  • 第17回 岡山 Gyro Meeting

    Role(s):Planning, management, etc., Panel moderator, session chair, etc.

    守屋和典  2025.2.15

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    Type:Academic society, research group, etc. 

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  • 第16回 岡山Gyro meeting

    Role(s):Planning, management, etc., Panel moderator, session chair, etc.

    森本規義  2021.7.10

     More details

    Type:Academic society, research group, etc. 

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  • Road to Gyro 1st

    Role(s):Review, evaluation

    2021.2.28

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    Type:Academic society, research group, etc. 

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