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Researcher Information

last modified:2024/01/08

Professor TANAKA Shigeo

Mail Laboratory Website

Faculty, Affiliation

Faculty of Frontier Engineering,Institute of Science and Engineering
Vice Dean of Graduate School of Natural Science and Technology

College and School Educational Field

Division of Mechanical Science and Engineering, Graduate School of Natural Science and Technology
Division of Mechanical Science and Engineering, Graduate School of Natural Science and Technology
School of Frontier Engineering, College of Science and Engineering

Laboratory

Bioengineering Laboratory

Academic Background

【Academic background(Doctoral/Master's Degree)】
Niigata University Master Graduate School, Division of Engineering 199108 Completed
Niigata University Doctor Graduate School of Science & Technology 199405 Completed
【Academic background(Bachelor's Degree)】
Niigata University 198903

Career

Japan Advanced Institute of Science and Technology School of Materials Science Research Associate(1994/04/01-1999/03/31)
Indiana University School of Medicine Research Fellow(1999/04/01-2002/06/30)
Indiana University School of Medicine Post-Doctoral Fellow(2002/07/01-2002/10/31)
Indiana University School of Medicine Assistant Scientist(2002/11/01-2004/04/29)
Kanazawa University Graduate School of Natural Sci. & Tech. Senior Lecturer(2004/04/30-2006/03/31)
Kanazawa University Graduate School of Natural Sci. & Tech. Associate Professor(2006/04/01-2007/02/28)
Kanazawa University Institute of Nature & Enviro. Tech. Associate Professor(2007/03/01-2015/03/31)
Kanazawa University Faculty of Mechanical Engineering, Institute of Science and Engineering Associate Professor(2015/04/01-2015/09/30)
Kanazawa University Faculty of Mechanical Engineering, Institute of Science and Engineering Professor(2015/10/01-2018/03/31)
Kanazawa University Faculty of Frontier Engineering, Institute of Science and Engineering Professor(2018/04/01-)

Year & Month of Birth

Academic Society

The Japan Society of Mechanical Engineers
The Japan Society of Mechanical Engineers

The Japan Society of Mechanical Engineers

Award

The Japan Society of Mechanical Engineers
○Recognized Reviewer in recognition of the review made for the journal, Bone(2017/05)
○Outstanding Reviewer(2016/01)
○Recognized Reviewer in recognition of the review made for the journal, Bone(2014/05)
○Recognized Reviewer in recognition of the review made for the journal, Bone(2014/05)
○Best Presentation Award, JSME Hokuriku-Shinetsu Branch(2007/03/08)

Specialities

Biomedical engineering/Biomaterial science and engineering、Materials/Mechanics of materials

Speciality Keywords

Biomedical Engineering, Biomechanics, Bone

Research Themes

Study on osteogenetic responses to mechanical stimulation

Development of a novel bone densitometer using near-infrared light

Study on osteogenic response to electrical stimulation

Books

Papers

  •  Osteoblast responses one hour after load-induced fluid flow in a three-dimensional porous matrix S. M. Tanaka, et al. CALCIFIED TISSUE INTERNATIONAL 76 4 261-271 2005/04
  •  Bone formation induced by a novel form of mechanical loading on joint tissue S. M. Tanaka, H. B. Sun, H. Yokota 18 2 41-44 2004/08
  •  Effects of high-impact mechanical loading on synovial cell cultures I. Sun, Y. Liu, S. M. Tanaka, et al. 3 37-43 2004/06
  •  Effects of broad frequency vibration on cultured osteoblasts S. M. Tanaka, J. Li, et al. JOURNAL OF BIOMECHANICS 36 1 73-80 2003/01
  •  Stochastic resonance in osteogenic response to mechanical loading S. M. Tanaka, M. I. Alam, C. H. Turner FASEB JOURNAL 17 2 313-314 2003/02

show all

  •  Intraocular pressure waves with exposure to pulsed Nd: YAG laser, the second and the third Harmonics Shigeo Tanaka 37 3 250-259 1999/06
  •  A new mechanical stimulator for cultured bone cells using piezoelectric actuator JOURNAL OF BIOMECHANICS 32 4 427-430 1999/04
  •  Analysis of intracellular calcium ion movement on osteoblast using confocal laser scanning microscope 17 409-413 1996/06
  •  Effects of pulse-vibration on the proliferation and the calcification of cultured osteoblasts 17 397-401 1996/10
  •  The effect of mechanical stimulation on the formation process of the bone-like tissue 34 4 331-334 1996/12
  •  Development of an apparatus applying mechanical stress to cultured osteoblasts 34 4 348-351 1996/06
  •  The finite element analysis involving trabecular structure 16 469-472 1995/08
  •  Mechanical properties of trabecular bone involving bone marrow 16 71-75 1995/08
  •  The effects of formalin preservation on the mechanical and AE properties of bone 15 1-6 1994/10
  •  Maintenance of bone mass by physical exercise after discontinuation of intermittent hPTH (1-34) administration 23 3 333-342 1993/12
  •  Failure characteristics of osteoporotic vertebral bodies monitored by acoustic emission SPINE 18 15 2314-2320 1993/11
  •  Failure characteristics of osteoporotic vertebral bodies 28 4 505-511 1993/04
  •  The effects of preservation on AE properties of bone 42 307-312 1993/11
  •  The influence of formalin preservation on AE responses and mechanical properties of long bone 14 217-220 1992/10
  •  Determination of a viscoelastic model of bone 40 259-266 1991/11
  •  Mechanical properties of osteopenic vertebral bodies monitored by acoustic emission BONE 14 5 737-743 1993/09
  •  Mechanical properties of osteoporotic vertebral bodies monitored by acoustic emission 13 99-103 1991/09
  •  Tensile force in soft tissue caused by callus distraction 11 215-219 1989/10
  •  Diaphyseal Bone Formation in Murine Tibiae in Response to Knee Loading P. Zhang, S.M. Tanaka, H. Jiang, M. Su, H. Yokota 100 5 1452-1459 2006/05
  •  Low-amplitude, broad-frequency vibration effects on cortical bone formation in mice A.B. Castillo, I. Alam, S.M. Tanaka, J. Levenda, J. Li, S.J. Warden, C.H. Turner BONE 39 5 1087-1096 2006/11
  •  Knee loading stimulates cortical bone formation in murine femurs P. Zhang, M. Su, S.M. Tanaka, H. Yokota BMC Musculoskeletal Disorders 7 73 0-0 2006/09
  •  Osteogenic potential with joint-loading modality H. Yokota, S.M. Tanaka JOURNAL OF BONE AND MINERAL METABOLISM 23 4 302-308 2005/06
  •  Bone densitometry by near-infrared spectroscopy .M. Tanaka, M. Nogawa, K. Yamakoshi 44 4 582-587 2006/12
  •  Development of a novel non-invasive bone densitometer using near-infrared lights 16 3 55-61 2006/12
  •  Frequency-dependent enhancement of bone formation in murine tibiae and femora with knee loading P. Zhang, S.M. Tanaka, Q. Sun, C.H. Turner, H. Yokota Journal of Bone and Mineral Metabolism 25 6  383-391 2007/11
  •  A novel bone densitometer using near-infrared light S.M. Tanaka, M. Nogawa, K. Yamakoshi, T. Tsujimoto Japanese Journal of Clinical Biomechanics 28  35-40 2007/11
  •  Non-destructive optical monitoring for calcification of tissue-engineered bone in vitro Shigeo M. Tanaka, Masafumi Kakio, Ken-ichi Yamakoshi Journal of Biomechanical Science and Engineering 3 3  332-342 2008/09
  •  Bone loss prevention by electrically-controlled muscle contraction Kanako Kondo, Takatomo Takimoto, Ken-ichi Yamakoshi, Shigeo M. Tanaka Japanese Journal of Clinical Biomechanics 29  199-204 2008/11
  •  Optical monitoring of in vitro calcification in tissue-engineered bone Masafumi Kakio, Naoki Sugiura, Ken-ichi Yamakoshi, Shigeo M. Tanaka Japanese Journal of Clinical Biomechanics 29  187-192 2008/11
  •  Development of optical bone densitometry - Compensation for skin variation by depth-resolved measurement - Shigeo. M. Tanaka, Tingshun Cao, Ken-ichi Yamakoshi, Toshiyuki Tsujimoto Japanese Journal of Clinical Biomechanics 29  181-186 2008/11
  •  Frequency and resting time dependencies of electrically-induced muscle contraction force Shigeo M. Tanaka and Kanako Kondo Journal of Biomechanical Science and Engineering 4 2  201-211 2009/05
  •  In vitro calcification of tissue engineered bone promoted by mechanical stimulation –Effect of cell seeding density and scaffold material-. Kohei Tachibana, Shigeo M. Tanaka Japanese Journal of Clinical Biomechanics 32 33-38 2011/10
  •  Moderate joint loading reduces degenerative actions of matrix metalloproteinases in the articular cartilage of mouse ulnae Hui B. Sun, Liming Zhao, Shigeo Tanaka, Hiroki Yokota Connective Tissue Research 53 2 180-186 2012/04
  •  Intracellular Ca2+ response of 3D-cultured osteoblasts subject to dynamic loading Shigeo M. Tanaka, Journal of Biomechanical Science and Engineering 7 3 318-327 2012/07
  •  Promotion of osteoblastic calcification by random pulse train electromagnetic fields Hiroyuki Matsumura, Shigeo M. Tanaka Japanese Journal of Clinical Biomechanics 33 41-46 2012/10
  •  Osteogenic effect of electrical muscle stimulation -Verification of the effect by finite element analysis of bone strain- Yuma Yorozuya. Jiro Sakamoto Shigeo M. Tanaka Japanese Journal of Clinical Biomechanics 34 71-76 2013/11
  •  Improvement of mechanical properties of tissue-engineered bone using a bovine trabecular bone ash scaffold-Intervention of electromagnetic field stimulation-, Yamashita Y., Tanaka SM. Proceedings of Life Engineering Symposium 2014 314-315 2014/09/17
  •  Effects of heating temperature on material properties of bovine trabecular bone ash scaffolds Tanaka SM., Yamashita Y. Proceedings of Life Engineering Symposium 2014 312-313 2014/09/17
  •  Effect of stimulation frequency on osteogenic capability of electrical muscle stimulation, Journal of Biomechanical Science and Engineering Shigeo M. Tanaka, Journal of Biomechanical Science and Engineering 9 3 14-00114 2014/12/26
  •  Frequency-dependence of mechanically stimulated osteoblastic calcification in tissue-engineered bone in vitro Shigeo M. Tanaka, Kohei Tachibana Annals of Biomedical Engineering 43 9 2083-2089 2015/01/07
  •  Random electromyostimulation promotes osteogenesis and the mechanical properties of rat bones Shigeo M. Tanaka, Yuma Yorozuya, Daisuke Takatsu Annals of Biomedical Engineering 45 12 2837-2846 2017/11/01
  •  Development of optical bone densitometry using near-infrared light Kaname Miura, Hidenori Matsubara, Shigeo M. Tanaka Journal of Mechanical Engineering 5 4 60-67 2018/03/31
  •  Electromyostimulation influences the mechanical properties and microarchitectures of bones beyond the stimulation site Ishak S. Limbong, Tomoki Yamamura, Shigeo M. Tanaka Journal of Biomechanical Science and Engineering 14 2 19-00034-19-00034 2019/05/28
  •  Optical bone densitometry robust to variation of soft tissue using machine learning techniques: validation by Monte Carlo simulation Kaname Miura, Anak Khantachawana, Shigeo M. Tanaka Biomedical Engineering / Biomedizinische Technik 27 5  056004 (16 pages) 2022/05/01
  •  Collagen cross-linking in osteoblastic cells promoted by randomized electrical stimulation Kunthika Mokdara, Tomoki Yamamura, Shigeo M. Tanaka Journal of Biomechanical Science and Engineering Article ID: 22-00173 (9 pages) 2022/12/14
  •  Optical Bone Densitometry Insensitive to Skin Thickness Kaname Miura, Anak Khantachawana, Tsuyoshi Wakamori, Hidenori Matsubara, and Shigeo M. Tanaka Biomedical Engineering / Biomedizinische Technik 67 6 503-512 2022/12/16

Conference Presentations

  • Non-invasive measurement of bone density without the influence of the skin layer using near-infrared light(conference:The 11th Asian-Pacific Conference on Biomechanics)(2021/11/06)
  • Evaluation of bioabsorbability of calcined bone using cultured osteoclasts(2017/12/14)
  • Improvement of prediction accuracy of optical bone density measuring device by Machine Learning(2018/03/02)
  • Develop of new artificial bone material using composite material of calcined bone powder / alginate acid(2018/03/02)
  • The effects of electromagnetic field stimulation on cell distribution and calcification in tissue-engineered bone(conference:Japan-Thailand Research Exchange Conference 2017)(2017/08/21)

show all

  • Study on accuracy verification of optical bone densitometer(conference:Japan-Thailand Research Exchange Conference 2017)(2017/08/21)
  • Development of optical bon edensitometry using near-infrared light(conference:Japan-Thailand Research Exchange Conference 2017)(2017/08/21)
  • A new method to predict stress around dental implants using 3D-finite element method (FEM) with patient computed tomography images and bite force data(2017/06/15)
  • The effectiveness of electro-myostimulation at rat quadriceps in increasing the mechanical properties of the lumbar vertebrae,(2017/07/23)
  • Development of optical bone densitometry using near-infrared light(conference:The 5th International Conference on Advances in Mechanical Engineering 2017 (ICAME 2017))(2017/08/16)
  • Implant Presence Influences Occlusal Force on Adjacent Tooth: Preliminary Results(conference:96th General Session of IADR)(2018/07/26)
  • Random electromyostimulation promotes osteogenesis and the mechanical properties of rat bone(conference:The 2nd International Conference and Exhibition on Sciences and Technology (ICEST))(2020/11/06)
  • Effects of Random Electric Stimulation on Osteoblastic Lysyl Oxidase Activities In Vitro,(2019/11/13)

Others

  •  Mechanical strength and mechano-compatibility of tissue-engineered bones CLINICAL CALCIUM 26 1 93-98 2016/01

Arts and Fieldwork

Patent

Theme to the desired joint research

○Promotion of osteogenesis by electrical stimulation

Grant-in-Aid for Scientific Research

○「ひずみ誘導型液体流動を用いた力学刺激適応型再生骨培養システムの開発」(2006-2007) 
○「骨芽細胞培養系を用いた骨欠損部充填材の開発」(1995-) 
○「骨芽細胞活性化に与えるひずみ量およびひずみ速度の影響」(1998-) 
○「ひずみ誘導型液体流動による骨形成反応促進効果の実験的検証」(2008-2010) 
○「骨量三次元有限要素モデルの応力からインプラント過重負担と辺縁骨吸収との関連を探る」(2020-2024) 
○「単一箇所での電気的筋刺激により全身の骨を強化する新手法の開発」(2019-2021) 
○「灰化ウシ海綿骨を担体とする高力学適合性再生骨の開発」(2015-2018) 
○「インプラント検討症例の残存歯咬合力を用いたヒト生体骨梁モデルの3次元有限要素解析」(2016-2018) 
○「光式骨密度計測装置の開発」(2014-2015)
○「骨の非線形力学刺激応答の検証とその数理モデル化」
○「ランダム性を有する物理刺激波形の骨形成促進効果の実験的検証」
○「力学的刺激の周波数チューニングによる骨形成促進の高効率化」

Competitive research funding,Contribution

Collaborative research,Consignment study

Classes (Bachelors)

○Internships B(2022)
○Internships A(2022)
○Internships B(2022)
○Strength of Materials I and Exercise(2022)
○Engineering Biomedical Materials B(2022)
○Engineering Biomedical Materials A(2022)
○Strength of Materials I and Exercise(2022)
○Internships A(2022)
○Strength of Materials I and Exercise(2022)
○Strength of Materials I and Exercise(2022)
○GS English Language for Undergraduates I (English for Science and Engineering)(2022)
○GS English Language for Undergraduates II (English for Science and Engineering)(2022)
○Innovation Methods and Mindset(2022)

Classes (Graduate Schools)

○Tissue Engineering(2022)
○Tissue Engineering(2022)
○Fundamentals of Biomechanics(2022)
○Fundamentals of Biomechanics(2022)
○Fundamentals of Biomechanics(2022)
○Fundamentals of Biomechanics(2022)
○Creative Research 1(2022)
○Creative Research 2(2022)
○Creative Research 2(2022)
○Creative Research 1(2022)

International Project

International Students

Lecture themes

Others (Social Activities)

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