{"id":3915,"date":"2022-06-09T18:18:21","date_gmt":"2022-06-09T09:18:21","guid":{"rendered":"https:\/\/c-mng.cwh.hokudai.ac.jp\/gcb.med\/Root\/?page_id=3915"},"modified":"2022-06-09T18:18:21","modified_gmt":"2022-06-09T09:18:21","slug":"publications2020","status":"publish","type":"page","link":"https:\/\/c-mng.cwh.hokudai.ac.jp\/gcb.med\/Root\/publications2020.html","title":{"rendered":"Publications: April 2020 \u2013 March 2021"},"content":{"rendered":"

International Collaborative Papers<\/h3>
  1. Nomura Y<\/u>, Tanaka S, Wang J, Shirato H, Shimizu S, Xing L<\/u>. Calibrated uncertainty estimation for interpretable proton computed tomography image correction using Bayesian deep learning. Phys Med Biol. 2021;66(6):065029.<\/li>
  2. Wu PH, Onodera Y,<\/u> Giaccia AJ, Le QT, Shimizu S, Shirato H, Nam JM<\/u>. Lysosomal trafficking mediated by Arl8b and BORC promotes invasion of cancer cells that survive radiation. Commun Biol. 2020;3(1):620.<\/li>
  3. Nomura Y, Wang J, Shirato H, Shimizu S, Xing L<\/u>. Fast spot-scanning proton dose calculation method with uncertainty quantification using a three-dimensional convolutional neural network. Phys Med Biol. 2020;65(21):215007.<\/li>
  4. Nishioka S<\/u>, Wu PH, Yakabe T, Giaccia AJ, Le QT,<\/u> Aoyama H, Shimizu S, Shirato H, Onodera Y, Nam JM<\/u>. Rab27b contributes to radioresistance and exerts a paracrine effect via epiregulin in glioblastoma. Neurooncol Adv. 2020;2(1):vdaa091.<\/li>
  5. Takayanagi T, Uesaka T, Nakamura Y, Unlu MB<\/u>, Kuriyama Y, Uesugi T, Ishi Y, Kudo N, Kobayashi M, Umegaki K, Tomioka S, Matsuura T. On-line range verification for proton beam therapy using spherical ionoacoustic waves with resonant frequency. Sci Rep. 2020 Nov 23;10(1):20385.<\/li>
  6. Xu Q, Wang J, Shirato H, Xing L<\/u>. Region-specific Dictionary Learning-based Low-dose Thoracic CT Reconstruction, arXiv:2010.09953 [physics.med-ph] 2020<\/li>
  7. Nakajima K, Hamada K, Ito R, Yoshida Y, Sutherland K, Ishikawa M<\/u>, Ozaki M, Shirato H<\/u>, Hamada T. Stability of d-luciferin for bioluminescence to detect gene expression in freely moving mice for long durations. Luminescence. 2021;36(1):94-98.<\/li>
  8. Hamada K, Oota A, Ito R, Kasahara S, Nakajima K, Kikuchi Y, Sutherland K<\/u>, Ishikawa M, Shirato H<\/u>, Ozaki M, Hamada T. Double recording system of Period1 gene expression rhythm in the olfactory bulb and liver in freely moving mouse. Biochem Biophys Res Commun. 2020;529(4):898-903.<\/li>
  9. Sawamura D, Narita H, Hashimoto N, Nakagawa S, Hamaguchi H, Fujima N<\/u>, Kudo K, Shirato H, Tha KK<\/u>. Microstructural Alterations in Bipolar and Major Depressive Disorders: A Diffusion Kurtosis Imaging Study. J Magn Reson Imaging. 2020;52(4):1187-1196.<\/li>
  10. Shimizu Y, Kudo K<\/u>, Kameda H, Harada T, Fujima N, Toyonaga T, Tha KK, Shirato H<\/u>. Prediction of Hypoxia in Brain Tumors Using a Multivariate Model Built from MR Imaging and 18F-Fluorodeoxyglucose Accumulation Data. Magn Reason Med Sci. 2020;19(3):227-234.<\/li>
  11. Nomura Y, Xu Q, Peng H, Takao S, Shimizu S, Xing L, Shirato H<\/u>. Modified Fast Adaptive Scatter kernel Superposition(mfASKS) Correction And Its Dosimetric Impact On CBCT-Based Proton Therapy Dose Calculation. Medical Physics. 47(1), January 2020<\/li>
  12. Fujima N<\/u>, Kameda H, Shimizu Y, Harada T, Tha KK<\/u>, Yoneyama M, Kudo K<\/u>. Utility of a diffusion-weighted arterial spin labeling (DW-ASL) technique for evaluating the progression of brain white matter lesions. Magn Reson Imaging. 2020 Jun; 69:81-87.<\/li>
  13. Ito R, Hamada K, Kasahara S, Kikuchi Y, Nakajima K, Sutherland K, Shirato H, <\/u>Ozaki M, Ishikawa M<\/u>, Hamada T. Mouse period1 gene expression recording from olfactory bulb under free moving conditions with a portable optic fibre device. Luminescence. 2020;35(8):1248-1253.<\/li>
  14. Fujima N<\/u>\u3001Kameda H\u3001Shimizu Y\u3001Harada T\u3001Tha KK<\/u>\u3001Yoneyama M\u3001Kudo K<\/u>\uff1aUtility of a diffusion-weighted arterial spin labeling (DW-ASL) technique for evaluating the progression of brain white matter lesions.<\/a>Magn Reson Imaging. 2020 Jun; 69:81-87. doi: 10.1016\/j.mri.2020.03.005. Epub 2020 Mar 23.<\/li>
  15. Taguchi A, Shishido S, Ou Y, Ikebe M, Zeng T, Fang W, Murakami K, Ueda T, Yasojima N, Sato K, Tamura K, Sutherland K<\/u>, Oki N, Chiba K, Minowa K, Uetani M, Kamishima T<\/u>. Quantification of Joint Space Width Difference on Radiography Via Phase-Only Correlation (POC) Analysis: a Phantom Study Comparing with Various Tomographical Modalities Using Conventional Margin-Contouring. J Digit Imaging. 2021;34(1):96-104.<\/li>
  16. Narisawa C, Sutherland K<\/u>, Lu Y, Furusaki A, Sagawa A, Kamishima T<\/u>. Validation of Fully Automatic Quantitative Software for Finger Joint Space Narrowing Progression for Rheumatoid Arthritis Patients. J Digit Imaging. 2020;33(6):1387-1392.<\/li>
  17. Fujiwara K, Fang W, Okino T, Sutherland K<\/u>, Furusaki A, Sagawa A, Kamishima T.<\/u> Quick and accurate selection of hand images among radiographs from various body parts using deep learning.
    J Xray Sci Technol. 2020;28(6):1199-1206. doi: 10.3233\/XST-200694. PMID: 32925161<\/li>
  18. Kato K, Sutherland K<\/u>, Tanaka Y, Kato M, Fukae J, Tanimura K, Kamishima T<\/u>. Fully automatic quantitative software for assessment of minute finger joint space narrowing progression on radiographs: evaluation in rheumatoid arthritis patients with long-term sustained clinical low disease activity. Jpn J Radiol. 2020 ;38(10):979-986.<\/li>
  19. Kwon J, Rajamahendiran RM, Virani NA, Kunjachan S, Snay E, Harlacher M, Myronakis M, Shimizu S, Shirato H<\/u>, Czernuszewicz TJ, Gessner R, Berbeco R. Use of 3-D Contrast-Enhanced Ultrasound to Evaluate Tumor Microvasculature After Nanoparticle-Mediated Modulation. Ultrasound Med Biol. 2020;46(2):369-376.<\/li>
  20. Tsoodol Z, Aikawa M<\/u>, Ichinkhorloo D, Khishigjargal T, Norov E, Komori Y, Haba H, Tak\u00e1cs S, Ditr\u00f3i F, Sz\u0171cs Z, Production cross sections of 45<\/sup>Ti in the deuteron-induced reaction on 45<\/sup>Sc up to 24 MeV, Applied Radiation and Isotopes 168 (2021) 109448, http:\/\/dx.doi.org\/10.1016\/j.apradiso.2020.109448<\/a><\/li>
  21. Tak\u00e1cs S, Aikawa M<\/u>, Haba H, Komori Y, Ditr\u00f3i F, Sz\u0171cs Z, Saito M, Murata T, Sakaguchi M, Ukon N, Cross sections of alpha-particle induced reactions on nat<\/sup>Ni: Production of 67<\/sup>Cu, Nuclear Instruments and Methods in Physics Research Section B 479 (2020) 125, http:\/\/dx.doi.org\/10.1016\/j.nimb.2020.06.022<\/a><\/li>
  22. Sun XH, Wang H, Otsu H, Sakurai H, Ahn DS, Aikawa M<\/u>, Fukuda N, Isobe T, Kawakami S, Koyama S, Kubo T, Kubono S, Lorusso G, Maeda Y, Makinaga A, Momiyama S, Nakano K, Nakayama S, Niikura M, Shiga Y, S\u00f6derstr\u00f6m PA, Suzuki H, Takeda H, Takeuchi S, Taniuchi R, Watanabe Y, Watanabe Y, Yamasaki H, Yang XF, Ye YL, Yoshida K, Spallation and fragmentation cross sections for 168 MeV\/nucleon 136<\/sup>Xe ions on proton, deuteron, and carbon targets, Physical Review C 101 (2020) 064623, https:\/\/doi.org\/10.1103\/PhysRevC.101.064623<\/a><\/li>
  23. Tsoodol Z, Aikawa M<\/u>, Dagvadorj I, Khishigjargal T, Javkhlantugs N, Komori Y, Haba H, Production cross sections of 68<\/sup>Ga and radioactive by-products in deuteron-induced reactions on natural zinc, Applied Radiation and Isotopes 159 (2020) 109095, 2020\u5e745\u6708, https:\/\/doi.org\/10.1016\/j.apradiso.2020.109095<\/a><\/li>
  24. Saito M, Aikawa M<\/u>, Murata T, Komori Y, Haba H, Tak\u00e1cs S, Ditr\u00f3i F, Sz\u0171cs Z, Production cross sections of 169<\/sup>Yb by the proton-induced reaction on 169<\/sup>Tm, Nuclear Instruments and Methods in Physics Research Section B 471 (2020) 13, https:\/\/doi.org\/10.1016\/j.nimb.2020.03.019<\/a><\/li>
  25. Zolbadral T, Aikawa M<\/u>, Ichinkhorloo D, Tegshjargal K, Komori Y, Haba H, Tak\u00e1cs S, Ditr\u00f3i F, Sz\u00fccs Z, Production cross sections of 45<\/sup>Ti via deuteron-induced reaction on 45<\/sup>Sc, Proceedings of the 2019 Symposium on Nuclear Data, 2020, 75, 2020\u5e7412\u6708<\/li>
  26. Saito M, Aikawa M<\/u>, Murata T, Komori Y, Haba H, Tak\u00e1cs S, Ditor\u00f3i F, Sz\u00fccs Z, Production of 169<\/sup>Yb by the proton-induced reaction on 169<\/sup>Tm, Proceedings of the 2019 Symposium on Nuclear Data, 2020, 79, 2020\u5e7412\u6708<\/li>
  27. Manabe O, Klein R, Katoh C<\/u>, Magota K, deKemp RA, Naya M, Tamaki N, Yoshinaga K. Validation of regional myocardial blood flow quantification using three-dimensional PET with rubidium-82: repeatability and comparison with two-dimensional PET data acquisition. Nucl Med Commun. 2020 Aug;41(8):768-775.<\/li>
  28. Prayongrat A, Srimaneekarn N, Srisawasdi S, Ito Y, Katoh N, Tamura M, Dekura Y, Toramatsu C, Chonlakiet Khorprasert C, Amornwichet N, Alisanant P, Hirata Y, Hayter A, Shirato H, Shimizu S<\/u>, Kobashi K<\/u>\uff1aConfidence interval assessing model in multivariable normal tissue complication probability for predicting radiation-induced liver disease in primary liver cancer. Journal of Radiation Research (in publish)\u00a0\u00a0<2021 Jan, accepted><\/li>
  29. Hampe N, Katscher U, van den Berg CAT, Tha KK<\/u>, Mandija S. Investigating the challenges and generalizability of deep learning brain conductivity mapping. Phys Med Biol. 2020 Jun 26;65(13):135001.<\/li>
  30. Inanc MT, Demirkan I, Ceylan C, Ozkan A, Gundogdu O, Goreke U,Gurkan GU, Unlu MB<\/u>, Quantifying the influences of radiation therapy on deformability of human red blood cells by dual-beam optical tweezers. RSC Advances 2021, accepted<\/li>
  31. Algarawi M, Erkol H, Luk A, Ha S, \u00dcnl\u00fc, MB<\/u>, Gulsen G, Nouizi F. Resolving tissue chromophore concentration at MRI resolution using multi-wavelength photo-magnetic imaging.\u00a0Biomedical Optics Express\u00a011, no. 8 (2020): 4244-4254.<\/li>
  32. Baba K, Kusumoto T, Okada S, Ogawara R, Kodaira S, Raffy Q, Barillon R, Ludwig N, Galindo C, Peaupardin P, Ishikawa M<\/u>. Quantitative estimation of track segment yields of water radiolysis species under heavy ions around Bragg peak energies using Geant4-DNA, Sci Rep. 11(1):1524. doi: 10.1038\/s41598-021-81215-6 (2021). [Corresponding author]<\/li>
  33. Kazumata K, Tokairin K, Ito M, Uchino H, Sugiyama T, Kawabori M, Osanai T, Tha KK<\/u>, Houkin K. Combined structural and diffusion tensor imaging detection of ischemic injury in moyamoya disease: relation to disease advancement and cerebral hypoperfusion. J Neurosurg. 2020 Apr 3:1-10.<\/li>
  34. Fujima N<\/u>, Andreu-Arasa VC, Onoue K, Weber PC, Hubbell RD, Setty BN, Sakai O. Utility of deep learning for the diagnosis of otosclerosis on temporal bone CT. Eur Radiol. 2021 Jan 6. doi: 10.1007\/s00330-020-07568-0.<\/li>
  35. Onoue K, Fujima N<\/u>, Andreu-Arasa VC, N Setty B, Qureshi MM, Sakai O. Cystic cervical lymph nodes of papillary thyroid carcinoma, tuberculosis and human papillomavirus positive oropharyngeal squamous cell carcinoma: Comparative CT analysis for their differentiation. Eur J Radiol. 2020 Nov;132:109310.<\/li>
  36. Ito K, Takumi K, Meibom SK, Qureshi MM, Fujima N<\/u>, Andreu-Arasa VC, Truong MT, Salama AR, Kaneda T, Sakai O. Risk assessment of osteoradionecrosis associated with periodontitis using\u00a018<\/sup>F-FDG PET\/CT. Eur J Radiol. 2020 Nov;132:109259.\u00a0<\/li>
  37. Fujima N<\/u>, Andreu-Arasa VC,Barest GD, Srinivasan A, Sakai O. Magnetic\u3000Resonance Spectroscopy of the Head and Neck: Principles, Applications, and\u3000 Neuroimaging Clin N Am. 2020 ;30(3):283-293.<\/li>
  38. Fujima N<\/u>, Andreu-Arasa VC, Meibom SK, Mercier GA, Salama AR, Truong MT, Sakai\u3000 Deep learning analysis using FDG-PET to predict treatment outcome in patients\u3000with oral cavity squamous cell carcinoma. Eur Radiol. 2020;30(11):6322-6330.<\/li>
  39. Fujima N<\/u>, Andreu-Arasa VC, Meibom SK, Mercier GA, Truong MT, Sakai O.\u3000Prediction of the human papillomavirus status in patients with oropharyngeal\u3000squamous cell carcinoma by FDG-PET imaging dataset using deep learning analysis:\u3000A hypothesis-generating study. Eur J Radiol. 2020;126:108936.<\/li>
  40. Demirkan I, Yaprak G, Ceylan C, Algul E, Tomruk CO, Bilen B, and Unlu MB<\/u>. Acoustic diagnosis of elastic properties of human tooth by 320 MHz scanning acoustic microscopy after radiotherapy treatment for head and neck cancer. Radiation Oncology 15 (2020): 1-10.<\/li>
  41. G\u00fczel\u00e7imen F, Tan\u00f6ren B, \u00c7etinkaya C, Kaya MD, Efkere H\u0130, \u00d6zen Y, Bing\u00f6l D, Unlu MB, et al. The effect of thickness on surface structure of rf sputtered TiO2 thin films by XPS, SEM\/EDS, AFM and SAM. Vacuum 182 (2020): 109766.<\/li>
  42. Altun B, Demirkan I, Isik EO, Kocaturk O, Unlu MB<\/u>, Garipcan B. Acoustic impedance measurement of tissue mimicking materials by using scanning acoustic microscopy. Ultrasonics 110 (2021): 106274.<\/li>
  43. Tsuneta S\u3001Oyama-Manabe N\u3001Kameda H\u3001Harada T\u3001Kato F\u3001Smit EJ\u3001Prokop M\u3001Kudo K<\/u>\uff1aImprovement of image quality on low-dose dynamic myocardial perfusion computed tomography with a novel 4-dimensional similarity filter.<\/a>Medicine (Baltimore). 2020 Jun 26;99(26):e20804. doi: 10.1097\/MD.0000000000020804.<\/li>
  44. Fujima N<\/u>, Andreu-Arasa VC, Meibom SK, Mercier GA, Salama AR, Truong MT, Sakai O\uff1aPrediction of the Treatment Outcome using Machine Learning with FDG-PET Image-based Multiparametric Approach in Patients with Oral Cavity Squamous Cell Carcinoma. Clin Radiol. 2021. in press.<\/li>
  45. Lee YH\u3001Quek ST\u3001Khong PL\u3001Lee CS\u3001Wu JS\u3001Zhang L\u3001Ng KH\u3001Yang SO\u3001Kudo K<\/u>\u3001Do KH\u3001Kim SH\u3001Chen DC\u3001Cheng A\u3001Leung JH\u3001Chang YC\u3001Hsu HH\u3001Chan WP\uff1aConsensus survey on pre-procedural safety practices in radiological examinations: a multicenter study in seven Asian regions.<\/a> Br J Radiol 2020 Sep;93(1113):20200082. doi: 10.1259\/bjr.20200082. Epub 2020 Jul 2.<\/li>
  46. Magota K, Numata N, Shinyama D, Katahata J, Munakata Y, Maniawski PJ, Kobayashi K, Manabe O, Hirata K, Tateishi U, Kudo K<\/u>, Shiga T\uff1aHalo Artifacts of Indwelling Urinary Catheter by Inaccurate Scatter Correction in 18F-FDG PET\/CT Imaging: Incidence Rate, Mechanism, and Solutions\u00a0EJNMMI Phys. 2020 Nov 13;7(1):66. doi: 10.1186\/s40658-020-00333-8.<\/li>
  47. Li Z, Kitajima K, Hirata K, Togo R, Takenaka J, Miyoshi Y, Kudo K<\/u>, Ogawa T, Haseyama M\uff1aPreliminary study of AI-assisted diagnosis using FDG-PET\/CT for axillary lymph node metastasis in patients with breast cancer\u00a0 \u00a0EJNMMI Research volume 11, Article number: 10 (2021)<\/li><\/ol>

    Other Original Papers \u2013 major paper only<\/h3>

    Japanese Journals (including those in English)<\/h4>
    1. Yasuda K, Minatogawa H, Dekura Y, Takao S<\/u>, Tamura M, Tsushima N, Suzuki T, Kano S, Mizumachi T, Mori T, Nishioka K, Shido M, Katoh N, Taguchi H, Fujima N, Onimaru R, Yokota I, Kobashi K, Shimizu S<\/u>, Homma A, Shirato H<\/u>, Aoyama H. Analysis of acute-phase toxicities of intensity-modulated proton therapy using a model-based approach in pharyngeal cancer patients. J Radiat Res. 2021;62(2):329-337.<\/li>
    2. Yamada T, Takao S<\/u>, Koyano H, Nihongi H, Fujii Y, Hirayama S, Miyamoto N, Matsuura T, Umegaki K, Katoh N, Yokota I, Shirato H, Shimizu S<\/u>. Validation of dose distribution for liver tumors treated with real-time-image gated spot-scanning proton therapy by log data based dose reconstruction. J Radiat Res. Accepted.<\/li>
    3. Nishio T, Nakamura M, Okamoto H, Kito S, Minemura T, Ozawa S, Kumazaki Y, Ishikawa M<\/u>, Tohyama N, Kurooka M, Nakashima T, Shimizu H, Suzuki R, Ishikura S, Nishimura Y. An overview of the medical-physics-related verification system for radiotherapy multicenter clinical trials by the Medical Physics Working Group in the Japan Clinical Oncology Group\u2013Radiation Therapy Study Group. Journal of Radiation Research, doi: 10.1093\/jrr\/rraa089 (2020)<\/li><\/ol>

      Overseas Journals<\/h4>
      1. Kasamatsu K, Matsuura T, Tanaka S, Takao S<\/u>, Miyamoto N, Nam JM, Shirato H, Shimizu S<\/u>, Umegaki K. The impact of dose delivery time on biological effectiveness in proton irradiation with various biological parameters. Med Phys. 2020;47(9):4644-4655.<\/li>
      2. Minatogawa H, Yasuda K, Dekura Y, Takao S<\/u>, Matsuura T, Yoshimura T, Suzuki R, Yokota I, Fujima N, Onimaru R, Shimizu S<\/u>, Aoyama H, Shirato H<\/u>. Potential benefits of adaptive intensity-modulated proton therapy in nasopharyngeal carcinomas. J Appl Clin Med Phys. 2021;22(1):174-183.<\/li>
      3. Yoshimura T, Shimizu S, Hashimoto T, Nishioka K<\/u>, Katoh N, Taguchi H, Yasuda K, Matsuura T, Takao S,<\/u> Tamura M, Tanaka S, Ito YM, Matsuo Y, Tamura H, Horita K, Umegaki K, Shirato H<\/u>. Quantitative analysis of treatments using real-time image gated spot-scanning with synchrotron-based proton beam therapy system log data. J Appl Clin Med Phys. 2020;21(12):10-19.<\/li>
      4. Nakamaru Y, Suzuki M, Kano S, Mizumachi T, Tsushima N, Suzuki T, Honma A, Nakazono A, Kimura S, Onimaru R, Yasuda K, Shirato H<\/u>, Homma A. The role of endoscopic resection for selected patients with sinonasal squamous cell carcinoma. Auris Nasus Larynx. 2021;48(1):131-137.<\/li>
      5. Miyata H, Osawa T, Abe T, Kikuchi H, Matsumoto R, Maruyama S, Nishioka K, Shimizu S, Hashimoto T, Shirato H<\/u>, Shinohara N. The updated outcomes of bladder- preserving trimodal therapy using a real-time tumor-tracking radiotherapy system for patients with muscle-invasive bladder cancer. Jpn J Clin Oncol. 2020;50(5):609-616.<\/li>
      6. Miyamoto N, Yokokawa K, Takao S<\/u>, Matsuura T, Tanaka S, Shimizu S, Shirato H<\/u>, Umegaki K. Dynamic gating window technique for the reduction of dosimetric error in respiratory-gated spot-scanning particle therapy: An initial phantom study using patient tumor trajectory data. J Appl Clin Med Phys. 2020 ;21(4):13-21.<\/li>
      7. Morita R, Abo D, Sakuhara Y, Soyama T, Katoh N, Miyamoto N, Uchinami Y, Shimizu S, Shirato H, Kudo K<\/u>. Percutaneous insertion of hepatic fiducial true- spherical markers for real-time adaptive radiotherapy. Minim Invasive Ther Allied Technol. 2020;29(6):334-343.<\/li>
      8. Shibata Y, Yasui H, Higashikawa K, Kuge Y<\/u>: Transferrin-based radiolabeled probe predicts the sensitivity of human renal cancer cell lines to ferroptosis inducer erastin. Biochem Biophys Rep. 2021; 26: 100957.<\/li>
      9. Manabe O, Yamaguchi S, Hirata K, Kobayashi K, Kobayashi H, Terasaka S, Toyonaga T, Magota K, Kuge Y<\/u>, Tamaki N, Shiga T, Kudo K<\/u>: Preoperative Texture Analysis Using 11C-Methionine Positron Emission Tomography Predicts Survival after Surgery for Glioma. Diagnostics (Basel). 2021; 11(2): 189.<\/li>
      10. Shimizu Y, Nakai Y, Watanabe H, Iikuni S, Ono M, Saji H, Kuge Y<\/u>, Saga T, Nakamoto Y: Increased [18F]FMISO accumulation under hypoxia by multidrug-resistant protein 1 inhibitors. EJNMMI Res. 2021;11(1) :9.<\/li>
      11. Tomaru U, Ito T, Ohmura Y, Higashikawa K, Miyajima S, Tomatsu R, Higashi T, Ishizu A, Kuge Y<\/u>, Yoshioka M, Kasahara M: Decreased Proteasomal Function Induces Neuronal Loss and Memory Impairment. Am J Pathol. 2021; 191(1): 144-156.<\/li>
      12. Yamasaki K, Zhao S, Nishimura M, Shimizu Y, Tamaki N, Takeda H, Kuge Y<\/u>: Effects of feeding condition on the myocardial and hepatic accumulation of radioiodine-labeled BMIPP in mice. Ann Nucl Med. 2021: 35(1): 59-64.<\/li>
      13. Nambu H, Takada S, Maekawa S, Matsumoto J, Kakutani N, Furihata T, Shirakawa R, Katayama T, Nakajima T, Yamanashi K, Obata Y, Nakano I, Tsuda M, Saito A, Fukushima A, Yokota T, Nio-Kobayashi J, Yasui H, Higashikawa K, Kuge Y<\/u>, Anzai T, Sabe H, Kinugawa S: Inhibition of xanthine oxidase in the acute phase of myocardial infarction prevents skeletal muscle abnormalities and exercise intolerance. Cardiovasc Res. 2021; 117(3): 805-819.<\/li>
      14. Oiwa Y, Oka K, Yasui H, Higashikawa K, Bono H, Kawamura Y, Miyawaki S, Watarai A, Kikusui T, Shimizu A, Okano H, Kuge Y<\/u>, Kimura K, Okamatsu-Ogura Y, Miura K: Characterization of brown adipose tissue thermogenesis in the naked mole-rat (Heterocephalus glaber), a heterothermic mammal. Sci Rep. 2020; 10(1): 19488.<\/li>
      15. Nishimoto Y, Nishio M, Nagashima S, Nakajima K, Ohira T, Nakai S, Nakase I, Higashikawa K, Kuge Y<\/u>, Matsumoto A, Ogawa M, Kojima C: Association of Hydrophobic Carboxyl-Terminal Dendrimers with Lymph Node-Resident Lymphocytes. Polymers (Basel). 2020; 12(7): 1474.<\/li>
      16. Watanabe S, Nishijima KI, Okamoto S, Magota K, Hirata K, Toyonaga T, Shiga T, Kuge Y<\/u>, Tamaki N: Biodistribution and internal radiation dosimetry of a novel probe for thymidine phosphorylase imaging, [123I]IIMU, in healthy volunteers. Ann Nucl Med. 2020; 34(8): 595-599.<\/li>
      17. Wang Z, Higashikawa K, Yasui H, Kuge Y<\/u>, Ohno Y, Kihara A, Midori YA, Houkin K, Kawabori M: FTY720 Protects Against Ischemia-Reperfusion Injury by Preventing the Redistribution of Tight Junction Proteins and Decreases Inflammation in the Subacute Phase in an Experimental Stroke Model. Transl Stroke Res. 2020; 11(5): 1103-1116.<\/li>
      18. Kobayashi K, Manabe O, Hirata K, Yamaguchi S, Kobayashi H, Terasaka S, Toyonaga T, Furuya S, Magota K, Kuge Y<\/u>, Kudo K, Shiga T, Tamaki N: Influence of the scan timepoint when assessing hypoxia in 18F-fluoromisonidazole PET: Two versus four hours. Eur J Nucl Med Mol Imaging 2020; 47(8):1833-1842.<\/li>
      19. Higashikawa K, Horiguchi S, Tarisawa M, Shibata Y, Ohkura K, Yasui H, Takeda H, Kuge Y<\/u>: Preclinical investigation of potential use of thymidine phosphorylase-targeting tracer for diagnosis of nonalcoholic steatohepatitis. Nucl Med Biol. 2020; 82-83: 25-32.<\/li>
      20. Ohnishi A, Ishizuka C, Tsubakihara K, Hirata Y<\/u>: Statistical double \u039b hypernuclear formation from \u039e- absorption at rest in light nuclei. PTEP. 2020(6):063D01.<\/li>
      21. Sakaguchi M, Aikawa M<\/u>, Saito M, Ukon N, Komori Y, Haba H, Activation cross section measurement of the deuteron-induced reaction on yttrium-89 for zirconium-89 production, Nuclear Instruments and Methods in Physics Research Section B 472 (2020) 59, https:\/\/doi.org\/10.1016\/j.nimb.2020.04.003<\/a><\/li>
      22. Naya M, Aikawa T, Manabe O, Obara M, Koyanagawa K, Katoh C<\/u>, Tamaki N. Elevated serum endothelin\u20111 is an independent predictor of coronary microvascular dysfunction in non\u2011obstructive territories in patients with coronary artery disease. Heart and Vessels 2021, DOI 10.1007\/s00380-020-01767-x<\/li>
      23. Kawakami M, Hirata K, Furuya S, Kobayashi K, Sugimori H, Magota K, Katoh C.<\/u> Development of Combination Methods for Detecting Malignant Uptakes Based on Physiological Uptake Detection Using Object Detection With PET-CT MIP Images. Front Med 2020. DOI 10.3389\/fmed.2020.616746<\/li>
      24. Habiba U, Hossain E, Yanagawa-Matsuda A, Chowdhury AFMA., Tsuda M, Zaman AU, Tanaka S, Higashino F.<\/u> Cisplatin Relocalizes RNA Binding Protein HuR and Enhances the Oncolytic Activity of E4orf6 Deleted Adenovirus. Cancers 12, 809. doi: 10.3390\/cancers12040809. (2020).<\/li>
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