Rchr
J-GLOBAL ID:200901094237827468   Update date: Nov. 20, 2024

Sakamoto Naoya

サカモト ナオヤ | Sakamoto Naoya
Affiliation and department:
Homepage URL  (2): http://www.comp.sd.tmu.ac.jp/mechanobio/http://db.tohoku.ac.jp/whois/detail/efe19ec8d16743174f3f603e517d0272.html
Research field  (1): Biomedical engineering
Research keywords  (3): Mechanobiology ,  生体力学 ,  Biomechanics
Research theme for competitive and other funds  (25):
  • 2023 - 2026 せん断応力負荷による血管平滑筋細胞の生体反応と大動脈解離偽腔拡大の関連性の検討
  • 2021 - 2024 Patient specific assessment of hemodynamics by computational fluid dynamics in patients with acute non-A non-B aortic dissection
  • 2020 - 2023 Influence of shear stress on human aortic endothelial cell/smooth muscle cell interaction in bicuspid aortic valve aortopathy
  • 2018 - 2021 Study on the role of the mechanical dynamics in the nucleus in cellular mechanical responses
  • 2018 - 2021 数値流体力学計算に基づく慢性大動脈解離における大動脈拡大機序の解明
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Papers (4):
  • Kaoru Sawasaki, Masanori Nakamura, Naoyuki Kimura, Koji Kawahito, Masashi Yamazaki, Hiromichi Fujie, Naoya Sakamoto. Endothelial-derived nitric oxide impacts vascular smooth muscle cell phenotypes under high wall shear stress condition. Biochemical and Biophysical Research Communications. 2024
  • Bo-Jiang Lin, Hiromichi Fujie, Masashi Yamazaki, Naoya Sakamoto. The Dual Effect of Fiber Density and Matrix Stiffness on A549 Tumor Multicellular Migration. Biochemical and Biophysical Research Communications. 2024
  • Kaoru Sawasaki, Yuta Horie, Masanori Nakamura, Naoyuki Kimura, Koji Kawahito, Naoya Sakamoto. Effect of mechanical environment caused by impinging jet flow on vascular endothelial cells. Transactions of Japanese Society for Medical and Biological Engineering. 2020. 58. 574-575
  • Toshiro Ohashi, Shouji Nakamura, Naoya Sakamoto, Masaaki Sato. Estimation of mechanical role of intracellular structures in smooth muscle cells by using traction force measurements. Proceedings of the 11th International Conference on Miniaturized Systems for Chemistry and Life Sciences, uTAS 2007. 2007. 134-136
MISC (250):
  • Takashi Miyano, Atsushi Suzuki, Naoya Sakamoto. Actin cytoskeletal reorganization is involved in hyperosmotic stress-induced autophagy in tubular epithelial cells. Biochemical and Biophysical Research Communications. 2023
  • Makoto Ohta, Naoya Sakamoto, Kenichi Funamoto, Zi Wang, Yukiko Kojima, Hitomi Anzai. A Review of Functional Analysis of Endothelial Cells in Flow Chambers. JOURNAL OF FUNCTIONAL BIOMATERIALS. 2022. 13. 3
  • Takashi Miyano, Atsushi Suzuki, Naoya Sakamoto. Calcium influx through TRPV4 channels involve in hyperosmotic stress-induced epithelial-mesenchymal transition in tubular epithelial cells. Biochemical and Biophysical Research Communications. 2022
  • Yuya Hiroshima, Yuki Oyama, Kaoru Sawasaki, Masanori Nakamura, Naoyuki Kimura, Koji Kawahito, Hiromichi Fujie, Naoya Sakamoto. A Compressed Collagen Construct for Studying Endothelial-Smooth Muscle Cell Interaction Under High Shear Stress. Annals of biomedical engineering. 2022. 50. 8. 951-963
  • Shingo Tsukamoto, Keng-Hwee Chiam, Takumi Asakawa, Kaoru Sawasaki, Naoyuki Takesue, Naoya Sakamoto. Compressive forces driven by lateral actin fibers are a key to the nuclear deformation under uniaxial cell-substrate stretching. Biochemical and Biophysical Research Communications. 2022. 597. 37-43
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Lectures and oral presentations  (42):
  • Morphological changes in cultured endothelial cells exposed to high shear stress and high shear stress gradient
    (MIT-NUS-NTU-Tohoku University Global COE Joint Workshop on Micro & Nano Bioengineering 2010)
  • Effect of Spatial Gradient of Shear Stress on Morphological Responses of Endothelial Cells to Flow
    (The 6th World Congress on Biomechanics 2010)
  • Effect of cyclic stretch on production of inflammatory cytokines from macrophages
    (The 6th World Congress on Biomechanics 2010)
  • yrosine Phosphorylation of Endothelial Cell-Cell Adhesion Proteins Induced by Shear Stress Gradient
    (BMES Annual Meeting 2010 2010)
  • Sorting of microtubules by length using micro-grooves fabricated on a chip
    (BMES Annual Meeting 2010 2010)
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Works (6):
  • 血流力学作用による血管壁リモデリング機構の工学的モデルの確立
    2007 -
  • 血流力学作用による血管壁リモデリング機構の工学的モデルの確立
    2007 -
  • 血流力学を考慮した内皮細胞による血管細胞の機能制御メカニズムの解明
    2004 - 2005
  • 血流力学を考慮した内皮細胞による血管細胞の機能制御メカニズムの解明
    2004 - 2005
  • 脳動脈分岐部における血流環境と内皮細胞の応答に関する研究
    2005 -
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Education (6):
  • - 2003 Tohoku University
  • - 2003 Tohoku University Graduate School, Division of Engineering Department of Mechatronics andPrecision Engineering
  • - 2000 Tohoku University Faculty of Engineering
  • - 2000 Tohoku University Faculty of Engineering Department of Mechatronics and Precision Engineering
  • - 1997 National Institute of Technology, Matsue College
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Professional career (1):
  • 博士(工学) (東北大学)
Work history (4):
  • 2020/04 - 現在 Tokyo Metropolitan University Department of Mechanical Systems Engineering Associate Professor
  • 2015/04 - 2019/03 Tokyo Metropolitan University Graduate School of Systems Design Associate Professor
  • 2012/04 - 2015/03 Kawasaki University of Medical Welfare Department of Medical Engineering Associate Professor
  • 2003/04 - 2012/03 Tohoku University Graduate School of Engineering Department of Bioengineering and Robotics, Biomechanics,Cell Biomechanics Assistant Professor
Committee career (2):
  • 2010 - 日本バイオレオロジー学会 編集委員
  • 2010 - 日本バイオレオロジー学会 編集委員
Awards (4):
  • 2008 - 第13回研究奨励賞
  • 2008 - 日本機械学会奨励賞
  • 2008 - 第13回研究奨励賞
  • 2008 - 日本機械学会奨励賞
Association Membership(s) (8):
日本バイオレオロジー学会 ,  日本生体医工学会 ,  日本機械学会 ,  日本バイオレオロジー学会 ,  Japanese Society of Biorheology ,  Japanese Society for Medical and Biological Engineering ,  The Japan Society of Mechanical Engineers ,  Biomedical Engineering Society (BMES)
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