Personnel Information

写真a

Shimabukuro Masaya


Job title

Assistant Professor
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Graduating School 【 display / non-display

  • Tokyo National College of Technology, 2015.03, Graduated

  • Tokyo Medical and Dental University, Graduate School of Medical and Dental Sciences, 2017.03, Graduated

  • Tokyo Medical and Dental University, Graduate School of Medical and Dental Sciences, 2020.03, Graduated

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Campus Career 【 display / non-display

  • 2015.04
    -
    2017.03
    Tokyo Medical and Dental University, Graduate School of Medical and Dental Sciences, Medical and Dental Sciences, Maxillofacial and Neck Reconstruction, Metals, Graduate Student
  • 2017.04
    -
    2020.03
    Tokyo Medical and Dental University, Graduate School of Medical and Dental Sciences, Life Science and Technology, Life Science and Technology, Metallic Biomaterials, Graduate Student
  • 2022.04
    -
    2023.03
    Tokyo Medical and Dental University, Institute of Biomaterials and Bioengineering, Biomedical Materials, Inorganic Biomaterials, Assistant Professor
  • 2023.04
    -
    Now
    Tokyo Medical and Dental University, Institute of Biomaterials and Bioengineering, -, -, Assistant Professor
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External Career 【 display / non-display

  • 2020.04
    -
    2022.03
    Kyushu University, Faculty of Dental Science, Research Assistant Professor
  • 2022.04
    -
    Now
    Tokyo Medical and Dental University, Assistant Professor
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Research Areas 【 display / non-display

  • Thin film/surface and interfacial physical properties

  • Biomaterials

  • Biomedical engineering

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Research Theme 【 display / non-display

  • Fabrication of antibacterial carbonate apatite bone substitute, 2020.09 - 2022.03

  • Fabrication of antibacterial carbonate apatite bone substitute, 2020.09 - 2022.03

  • Fabrication of antibacterial carbonate apatite bone substitute, 2020.09 - 2022.03

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Published Papers & Misc 【 display / non-display

  1. Koichiro Hayashi, Masaya Shimabukuro, Cheng Zhang, Ahmad Nazir Taleb Alashkar, Ryo Kishida, Akira Tsuchiya, Kunio Ishikawa. Silver phosphate-modified carbonate apatite honeycomb scaffolds for anti-infective and pigmentation-free bone tissue engineering 2024.08; 27 101161. ( DOI )

  2. Zhibin Wang, Masaya Shimabukuro, Ryo Kishida, Taishi Yokoi, Masakazu Kawashi. Effects of pH on the Microarchitecture of Carbonate Apatite Granules Fabricated Through a Dissolution–Precipitation Reaction Frontiers in Bioengineering and Biotechnology. 2024.06; 12 1396275. ( PubMed, DOI )

  3. Sung, PC; Yokoi, T; Shimabukuro, M; Mokudai, T; Kawashita, M. Apatite-Forming Ability and Visible Light-Enhanced Antibacterial Activity of CuO-Supported TiO2 Formed on Titanium by Chemical and Thermal Treatments JOURNAL OF FUNCTIONAL BIOMATERIALS. 2024.04; 15 (5): ( PubMed, DOI )

  4. 島袋将弥. 骨・関節領域感染制御のためのバイオマテリアル開発 まてりあ. 2024.04; 63 (4): 243-247. ( DOI )

  5. Katada Haruko, Inokoshi Masanao, Kamijo Singo, Liu Hengyi, Xu Kaiqi, Kawashita Masakazu, Yokoi Taishi, Shimabukuro Masaya, Minakuchi Shunsuke. Effects of multiple firings on the translucency, crystalline phase, and mechanical strength of highly translucent zirconia Dental Materials Journal. 2024.03; 43 (2): 294-302. ( ichushi )

  6. Shimabukuro, M; Morinobu, M; Tsuchiya, A; Kishida, R; Kawashita, M; Ishikawa, K. Antibacterial and osteogenic thin films on Ti-6Al-4V surface formed by passivation process in copper hydroxide solution SCIENCE AND TECHNOLOGY OF ADVANCED MATERIALS. 2024.02; 25 (1): 2303327. ( PubMed, DOI )

  7. Katada H, Inokoshi M, Kamijo S, Liu H, Xu K, Kawashita M, Yokoi T, Shimabukuro M, Minakuchi S. Effects of multiple firings on the translucency, crystalline phase, and mechanical strength of highly translucent zirconia. Dental materials journal. 2024; 43 (2): 294-302. ( PubMed, DOI )

  8. Katada H, Inokoshi M, Kamijo S, Liu H, Xu K, Kawashita M, Yokoi T, Shimabukuro M, Minakuchi S. Effects of multiple firings on the translucency, crystalline phase, and mechanical strength of highly translucent zirconia. Dent Mater J. 2023.11;

  9. Aoki S, Shimabukuro M, Kishida R, Kyuno K, Noda K, Yokoi T, Kawashita M. Electrochemical Deposition of Copper on Bioactive Porous Titanium Dioxide Layer: Antibacterial and Pro-Osteogenic Activities. ACS applied bio materials. 2023.11; 6 (12): 5759-5767. ( PubMed, DOI )

  10. Kubota, M; Furuya, M; Yokota, K; Kanetaka, H; Ogawa, T; Saito, S; Jeyadevan, B; Shimabukuro, M; Yokoi, T; Kawashita, M. Proliferation and differentiation of MC3T3-E1 cells on polymethyl methacrylate cements containing Fe3O4 and TiO2 for hyperthermic treatment of metastatic bone tumors JOURNAL OF BIOMATERIALS APPLICATIONS. 2023.10; 38 (5): 605-613. ( PubMed, DOI )

  11. Taishi Yokoi, Masahiro Watanabe, Yuejun Wang, Tomoyo Goto, Tohru Sekino, Masaya Shimabukuro, Masakazu Kawashita. Synthesis and fluorescence properties of octacalcium phosphate with incorporated pyridinedicarboxylate ions Journal of the Ceramic Society of Japan. 2023.10; 131 (10): 701-707. ( DOI )

  12. Tan, JLT; Shimabukuro, M; Kobayashi, M; Kishida, R; Kawashita, M; Ishikawa, K. Ant‐nest type porous scaffold with micro‐struts consisting of carbonate apatite for promoting bone formation and scaffold resorption Journal of biomedical materials research. Part A. 2023.09; 112 (1): 31-43. ( PubMed, DOI )

  13. Masaya Shimabukuro, Mamiko Kobayashi, Masakazu Kawashita. Metallic Substrate Influences on the Osteogenic Cell Compatibility and Antibacterial Activity of Silver-Incorporated Porous Oxide Layers Formed by Micro-Arc Oxidation 2023.08; 1 (8): 2288-2294. ( DOI )

  14. Kanae Suzuki, Misato Iwatsu, Takayuki Mokudai, Maiko Furuya, Kotone Yokota, Hiroyasu Kanetaka, Masaya Shimabukuro, Taishi Yokoi, Masakazu Kawashita. Visible-Light-Enhanced Antibacterial Activity of Silver and Copper Co-Doped Titania Formed on Titanium via Chemical and Thermal Treatments Molecules. 2023.01; 28 (2): 650. ( PubMed, DOI )

  15. Yokoi T, Watanabe M, Nakamura F, Kimura-Suda H, Shimabukuro M, Kawashita M. Formation of octacalcium phosphate with incorporated dicarboxylate ions containing disulfide bonds. Dalton transactions (Cambridge, England : 2003). 2023; 52 (45): 16586-16590. ( PubMed, DOI )

  16. Yokoi T, Watanabe M, Goto T, Meng S, Sekino T, Shimabukuro M, Kawashita M. Synthesis of Octacalcium Phosphate Containing Glutarate Ions with a High Incorporation Fraction. Materials (Basel, Switzerland). 2022.12; 16 (1): 64. ( PubMed, DOI )

  17. Tan Janice Lay Tin, Shimabukuro Masaya, Kishida Ryo, Ishikawa Kunio. Fabrication and histological evaluation of ant-nest type porous carbonate apatite artificial bone using polyurethane foam as a porogen Journal of Biomedical Materials Research Part B: Applied Biomaterials . 2022.10; 111 (3): 560-567. ( PubMed, DOI )

  18. Yokoi Taishi, Shimabukuro Masaya, Kawashita Masakazu. Octacalcium phosphate with incorporated carboxylate ions: a review Science and Technology of Advanced Materials. 2022.07; 23 (1): 434-445. ( PubMed, DOI )

  19. Koichiro Hayashi, Toshiki Yanagisawa, Masaya Shimabukuro, Ryo Kishida, Kunio Ishikawa. Granular honeycomb scaffolds composed of carbonate apatite for simultaneous intra- and inter-granular osteogenesis and angiogenesis. Materials today. Bio. 2022.03; 14 100247. ( PubMed, DOI )

  20. Masaya Shimabukuro, Koichiro Hayashi, Ryo Kishida, Akira Tsuchiya, Kunio Ishikawa. Surface functionalization with copper endows carbonate apatite honeycomb scaffold with antibacterial, proangiogenic, and pro-osteogenic activities. Biomaterials advances. 2022.03; 135 212751. ( PubMed, DOI )

  21. Elsheikh M, Kishida R, Hayashi K, Tsuchiya A, Shimabukuro M, Ishikawa K. Effects of pore interconnectivity on bone regeneration in carbonate apatite blocks. Regenerative biomaterials. 2022.02; 9 (1): rbac010. ( PubMed, DOI )

  22. Freitas P, Kishida R, Hayashi K, Tsuchiya A, Shimabukuro M, Ishikawa K. Fabrication and histological evaluation of porous carbonate apatite blocks using disodium hydrogen phosphate crystals as a porogen and phosphatization accelerator. Journal of biomedical materials research. Part A. 2022.02; 110 (6): 1278-1290. ( PubMed, DOI )

  23. Koichiro Hayashi, Akira Tsuchiya, Masaya Shimabukuro, Kunio Ishikawa. Multiscale Porous Scaffolds Constructed of Carbonate Apatite Honeycomb Granules for Bone Regeneration Materials & Design. 2022.02; 14 110468. ( DOI )

  24. Masaya Shimabukuro, Koichiro Hayashi, Ryo Kishida, Akira Tsuchiya, Kunio Ishikawa. Effects of carbonate ions in phosphate solution on the fabrication of carbonate apatite through a dissolution–precipitation reaction Ceramics International. 2022.01; 48 (1): 1032-1037. ( DOI )

  25. Hayashi K, Shimabukuro M, Ishikawa K. Antibacterial Honeycomb Scaffolds for Achieving Infection Prevention and Bone Regeneration. ACS applied materials & interfaces. 2022.01; 14 (3): 3762-3772. ( PubMed, DOI )

  26. Shimabukuro M, Hayashi K, Kishida R, Tsuchiya A, Ishikawa K. No-Observed-Effect Level of Silver Phosphate in Carbonate Apatite Artificial Bone on Initial Bone Regeneration. ACS infectious diseases. 2022.01; 8 (1): 159-169. ( PubMed, DOI )

  27. Koichiro Hayashi, Masaya Shimabukuro, Ryo Kishida, Akira Tsuchiya, Kunio Ishikawa. Structurally Optimized Honeycomb Scaffolds with Outstanding Ability for Vertical Bone Augmentation Journal of Advanced Research. 2022.01; 41 101-112. ( DOI )

  28. Koichiro Hayashi, Masaya Shimabukuro, Ryo Kishida, Akira Tsuchiya, Kunio Ishikawa. Honeycomb Scaffolds Capable of Achieving Barrier Membrane-Free Guided Bone Regeneration Materials Advances. 2021.09; 2 (23): 7638-7649. ( DOI )

  29. Tsutsumi Harumi, Tsutsumi Yusuke, Shimabukuro Masaya, Manaka Tomoyo, Chen Peng, Ashida Maki, Ishikawa Kunio, Katayama Hideki, Hanawa Takao. Investigation of the Long-Term Antibacterial Properties of Titanium by Two-Step Micro-Arc Oxidation Treatment Coatings. 2021.07; 11 (7): 798. ( DOI )

  30. Shimabukuro Masaya, Tsutsumi Harumi, Tsutsumi Yusuke, Manaka Tomoyo, Chen Peng, Ashida Maki, Ishikawa Kunio, Katayama Hideki, Hanawa Takao. Enhancement of antibacterial property of titanium by two-step micro arc oxidation treatment Dental Materials Journal. 2021.05; 40 (3): 592-598. ( ichushi )

  31. Shimabukuro Masaya, Tsutsumi Harumi, Tsutsumi Yusuke, Manaka Tomoyo, Chen Peng, Ashida Maki, Ishikawa Kunio, Katayama Hideki, Hanawa Takao. Enhancement of antibacterial property of titanium by two-step micro arc oxidation treatment DENTAL MATERIALS JOURNAL. 2021.05; 40 (3): 592-598. ( PubMed, DOI )

  32. Magda Dziaduszewska, Masaya Shimabukuro, Tomasz Seramak, Andrzej Zieliński, Takao Hanawa. Formation and characterization of anodic titanium oxide films containing Ca, P and Si ions on selective-laser melted Ti13Zr13Nb alloy Engineering of Biomaterials. 2021; 24 (163):

  33. Shimabukuro M. Antibacterial Property and Biocompatibility of Silver, Copper, and Zinc in Titanium Dioxide Layers Incorporated by One-Step Micro-Arc Oxidation: A Review. Antibiotics (Basel, Switzerland). 2020.10; 9 (10): 716. ( PubMed, DOI )

  34. Hiji Akari, Hanawa Takao, Shimabukuro Masaya, Chen Peng, Ashida Maki, Ishikawa Kunio. Initial formation kinetics of calcium phosphate on titanium in Hanks' solution characterized using XPS Surface and Interface Analysis. 2020.10; 53 (2): 185-193. ( DOI )

  35. Shimabukuro Masaya, Tsutsumi Yusuke, Nozaki Kosuke, Chen Peng, Yamada Risa, Ashida Maki, Doi Hisashi, Nagai Akiko, Hanawa Takao. Investigation of antibacterial effect of copper introduced titanium surface by electrochemical treatment against facultative anaerobic bacteria Dental Materials Journal. 2020.08; 39 (4): 639-647. ( DOI )

  36. Dziaduszewska Magda, Shimabukuro Masaya, Seramak Tomasz, Zielinski Andrzej, Hanawa Takao. Effects of Micro-Arc Oxidation Process Parameters on Characteristics of Calcium-Phosphate Containing Oxide Layers on the Selective Laser Melted Ti13Zr13Nb Alloy Coatings. 2020.07; 10 (8): 745. ( DOI )

  37. Shimabukuro M, Tsutsumi Y, Nozaki K, Chen P, Yamada R, Ashida M, Doi H, Nagai A, Hanawa T. Investigation of antibacterial effect of copper introduced titanium surface by electrochemical treatment against facultative anaerobic bacteria. Dental materials journal. 2020.07; 39 (4): 639-647. ( PubMed, DOI )

  38. Shimabukuro Masaya, Hiji Akari, Manaka Tomoyo, Nozaki Kosuke, Chen Peng, Ashida Maki, Tsutsumi Yusuke, Nagai Akiko, Hanawa Takao. Time-Transient Effects of Silver and Copper in the Porous Titanium Dioxide Layer on Antibacterial Properties Journal of Functional Biomaterials. 2020.06; 11 (2): 44. ( PubMed, DOI )

  39. Shimabukuro Masaya, Manaka Tomoyo, Tsutsumi Yusuke, Nozaki Kosuke, Chen Peng, Ashida Maki, Nagai Akiko, Hanawa Takao. Corrosion Behavior and Bacterial Viability on Different Surface States of Copper Materials Transactions. 2020; 61 (6): 1143-1148. ( DOI )

  40. Shimabukuro Masaya, Tsutsumi Yusuke, Yamada Risa, Ashida Maki, Chen Peng, Doi Hisashi, Nozaki Kosuke, Nagai Akiko, Hanawa Takao. Investigation of Realizing Both Antibacterial Property and Osteogenic Cell Compatibility on Titanium Surface by Simple Electrochemical Treatment ACS Biomaterials Science & Engineering. 2019.11; 5 (11): 5623-5630. ( PubMed, DOI )

  41. Shimabukuro Masaya, Tsutsumi Yusuke, Nozaki Kosuke, Chen Peng, Yamada Risa, Ashida Maki, Doi Hisashi, Nagai Akiko, Hanawa Takao. Chemical and Biological Roles of Zinc in a Porous Titanium Dioxide Layer Formed by Micro-Arc Oxidation Coatings. 2019.10; 9 (11): ( DOI )

  42. Shimabukuro Masaya, Ito Haruka, Tsutsumi Yusuke, Nozaki Kosuke, Chen Peng, Yamada Risa, Ashida Maki, Nagai Akiko, Hanawa Takao. The Effects of Various Metallic Surfaces on Cellular and Bacterial Adhesion Metals. 2019.10; 9 (11): ( DOI )

  43. DRN Correa, LA Rocha, AR Ribeiro, S Gemini-Piperni, BS Archanjo, CA Achete, J Werckmann, CRM Afonso, M Shimabukuro, H Doi, Y Tsutsumi, T Hanawa. Growth mechanisms of Ca- and P-rich MAO films in Ti-15Zr-xMo alloys for osseointegrative implants Surface and Coatings Technology. 2018.06; 344 373-382. ( DOI )

  44. Masaya Shimabukuro, Yusuke Tsutsumi, Maki Ashida, Peng Chen, Hisashi Doi, Takao Hanawa. Electrochemical Surface Treatment for Controlling the Release of Silver Ion As Antibacterial Agent on Titanium ECS Meeting Abstracts. 2016.09; (53): 4030.

  45. Yusuke Tsutsumi, Mitsuo Niinomi, Masaaki Nakai, Masaya Shimabukuro, Maki Ashida, Peng Chen, Hisashi Doi, Takao Hanawa. Electrochemical Surface Treatment of a β-titanium Alloy to Realize an Antibacterial Property and Bioactivity Metals. 2016.03; 6 (4): ( DOI )

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Conference Activities & Talks 【 display / non-display

  1. Y. Tsutsumi, M. Shimabukuro, T. Manaka, M. Goto, M. Kaodowaki, H, Katayama, M. Kawashita, T. Ishimoto, T. Hanawa. Improvement of corrosion resistance and biosafety for martensitic stainless steel by laser thermal processing. Biomaterials International 2024 2024.07.03

  2. R. Miyake, M. Shimabukuro, E. Marukawa, M. Kawashita. Biodegradable coating consisting of Mg and Ca for enhancing both antibacterial activity and osteogenesis. Biomaterials International 2024 2024.07.02

  3. M. Shimabukuro, S. Aoki, R. Kishida, T. Yokoi, M. Kawashita. Endowing antibacterial activity to titanium and tantalum surfaces by micro-arc oxidation. Biomaterials International 2024 2024.07.02

  4. M. Shimabukuro, M. Kawashita, K. Ishikawa. ANTIBACTERIAL CARBONATE APATITE ARTIFICIAL BONE FOR BONE REGENERATION AND INFECTION PREVENTION. Biomaterial international 2023 (BMI2023) 2023.07.31

  5. Masaya Shimabukuro, Koichiro Hayashi, Taishi Yokoi, Masakazu Kawashita, Kunio Ishikawa. Surface Functionalization of Honeycomb Scaffolds Consisting of Carbonate Apatite for Bone Regeneration and Infection Prevention. Visual-JW 2022 & DEJI2MA-2 2022.10.25

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Awards & Honors 【 display / non-display

  • Best Poster Paper Award,Biomaterials International 2024,2024.07

  • Best Poster Paper Award,Biomaterials International 2023 (BMI2023),2023.08

  • Outstanding Presentation Award,International Conference on Materials and Systems for Sustainability (ICMaSS) 2019,2019.11

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Campus class subject 【 display / non-display

  • Advanced Biomaterials Science,2023 - Now

  • Applied Biomaterials,2023 - Now

  • Tissue Regenerative Bioceramic Materials Science,2022 - Now

  • Tissue Regenerative Bioceramic Materials Science,2022 - Now

  • Applied Biomaterials,2022 - Now

  • Advanced Biomaterials Science,2022 - Now

  • Basic-Clinical Borderless Education,2022 - Now

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