Journal papers

Original papers

2021

  • Natsume,, T., Oishi, M., Oshima, N., Mukai, N., “Droplet Formulation Method for Viscous Fluid Injection Considering the Effect of Liquid-Liquid Two-Phase Flow”, ITE Transactions on Media Technology and Applications, Vol.9(1), pp. 3-41, (2021)
  • Yamada S., Ito H., Ishikawa M., Yamamoto K., Yamaguchi M., Oshima M., Nozaki K., “Quantification of oscillatory shear stress from reciprocating cerebrospinal fluid motion on four-dimensional flow imaging”, American Journal of Neuroradiology, Vol.42(3), pp. 479-486, (2021)
  • 大島まり, 「血流シミュレーションによる内頸動脈狭窄症の脳循環に与える影響の検証」,『化学工学』Vol.85(2), pp. 84-86, (2021)
  • Matsuura, S., Takayama, T., Yuhn, C., Oshima, M., Shirasu, T., Akai, T., Isaji, T., Hoshina, K., “Carotid Stump Pressure and Contralateral Internal Carotid Stenosis Ratio During Carotid Endarterectomies: 1D-0D Hemodynamic Simulation of Cerebral Perfusion”, Annals of Vascular Diseases, Vol.14(1), pp. 1-7, (2021)

2020

  • Yamada S., Ishikawa M., Ito H., Yamamoto K., Yamaguchi M., Oshima M., Nozaki K., “Cerebrospinal fluid dynamics in idiopathic normal pressure hydrocephalus on four-dimensional flow imaging”, European Radiology, Vol.30(8), pp. 4454-4465, (2020)
  • Kobayashi, M., Hoshina, K., Nemoto, Y., Takagi, S., Shojima, M., Hayakawa, M., Yamada, S., Oshima, M., “A penalized spline fitting method to optimize geometric parameters of arterial centerlines extracted from medical images”, Computerized Medical Imaging and Graphics, Vol.84, pp. 101746, doi: 10.1016/j.compmedimag.2020.101746, (2020)
  • 大島まり, 山田茂樹, 「脳神経外科と数理学(8)脳血管疾患における血流の数値流体力学」,『脳神経外科』Vol.48(8), pp. 750-757, (2020)
  • Takagi, K., Watahiki, R., Machida, T., Onouchi, K., Kato, K., Oshima, M., “Reliability and Inter-observer Variability of Evans’ Index and Disproportionately Enlarged Subarachnoid Space Hydrocephalus as Diagnostic Criteria for Idiopathic

2019

  • C. Yuhn, K. Hoshina, K. Miyahara, M. Oshima, “Computational simulation of flow-induced arterial remodeling of the pancreaticoduodenal arcade associated with celiac artery stenosis,” Journal of Biomechanics 92, pp.146–154, 2019 (doi: 10.1016/j.jbiomech.2019.05.043)
  • Oshima M., Liang F., 「マルチスケール血流シミュレーションを用いた血行力学的刺激の予測」, 生体の科学 70(4), pp. 339-343, (2019)
  • Natsume T., Oishi M., Oshima M., Mukai N., 「粒子法による液滴の滴下挙動再現と定量的評価」, 芸術科学会論文誌 Vol. 18, No. 3 pp. 106-113 (2019)
  • 夏目拓也、大石正道、向井信彦、大島まり, “界面張力モデルによる脳動脈瘤用塞栓材液滴形成の比較”, 日本バイオレオロジー学会誌, Vol.33(2), p. 36 (2019)
  • Miyahara, K., Hoshina, K., Nitta, J., Kimura, M., Yamamoto, S., Ohshima, M., “Hemodynamic Simulation of Pancreaticoduodenal Artery Aneurysm Formation Using an Electronic Circuit Model and a Case Series Analysis.”, Ann Vasc Dis., Vol.12(2), pp. 176-181 (2019)
  • Johari, N. H., Wood, N. B., Cheng, Z., Torii, R., Oishi, M., Oshima, M., Xu, X. Y., “Disturbed Flow in a Stenosed Carotid Artery Bifurcation: Comparison of RANS-Based Transitional Model and LES with Experimental Measurements”, International Journal of Applied Mechanics, Vol. 11(4), 1950032-1-21, (2019)
  • Kimura, M., Hoshina, K., Kobayashi, M., Yamamoto, S., Ohshima, M., Watanabe, T., “Morphological analysis using geometric parameters for splenic aneurysms”, Asian Cardiovasc Thorac Ann, Vol.26, No.2, pp. 133-138, (2019)
  • Kimura, M., Hoshina, K., Miyahara, K., Nitta, J., Kobayashi, M., Yamamoto, S., Ohshima, M., “Geometric analysis of ruptured and nonruptured abdominal aortic aneurysms”, J Vasc Surg., Vol.69, No.1, pp. 86-91, (2019)
  • Yamada, S., Ishikawa, M, Yamamoto, K., Yamaguchi, M., Oshima, M., “Location-specific characteristics of perivascular spaces as the brain’s interstitial fluid drainage system”, Journal of the Neurological Sciences, Vol.398, pp. 9-15, (2019)

2018

  • Oishi M, Kinoshita H, Fujii T and Oshima M 2018 “Phase-locked confocal micro-PIV measurement for 3D flow structure of transient droplet formation mechanism in T-shaped microjunction” Meas. Sci. Technol. 29 115204 (17pp) doi: 10.1088/1361-6501/aadff9
  • Yoshiyuki Morita, Tsukasa Matsuo, Shingo Maeda, Masamichi Oishi, and Marie Oshima “Three-dimensional displacement measurement of self-oscillating gel using digital holographic microscopy” Applied Optics Vol. 57, Issue 36, pp. 10541-10547 (2018) doi: 10.1364/AO.57.010541
  • N. Mukai, Y. Matsuura, M. Oishi, M. Oshima, Chromatic Aberration Based Depth Estimation in a Fluid Field, Journal of Image and Graphics, vol.6, no.1, pp.59-63, 2018
  • A. Winzen, M. Oishi, M. Oshima, A numerical model‑assisted experimental design study of inertia‑based particle focusing in stepped microchannels, Microfluidics and Nanofluidics, vol.22, no.28, 18pp, 2018

2017

  • Hoshina, K., Oshima, M., Watanabe, T., Yamamoto, S., Theoretical mechanism of temporary renal function improvement after abdominal aortic aneurysm surgery: Applications for clinical imaging and laboratory data, Medicine, Volume. 96, Issue 30, p e7428, 2017
  • Yajima, Y., Oshima, M., Iwai, T., Kitajima, H., Omura, S., Tohnai, I., Computational fluid dynamic study of the pharyngeal airway space before and after mandibular setback surgery in patients with mandibular prognathism, International Journal of Oral and Maxillofacial Surgery, Volume 46, Issue 7, pp. 839-844, 2017
  • Kitajima, H., Oshima, M., Iwai1, T, Ohhara1, Y., Yajima1, Y., Mitsudo, K., Computational fluid dynamics study of intra-arterial chemotherapy for oral cancer, ioMedical Engineering, vol.16, No.57, pp.1-26, 2017
  • 大島まり, 早川基治, 動脈硬化症病変に関する医用画像からの血管の三次元形状モデリングと血流シミュレーション, Cardio-Renal Diabetes, Vol.6, No.2, pp.4-7, 2017

2016

  • Zhang, H., Fujiwara, N., Kobayashi, M., Yamada, S., Liang, F., Takagi, S., Oshima, M., Development of a numerical method for patient-specific cerebral circulation using 1D-0D simulation of the entire cardiovascular system with SPECT data, Annals of biomedical engineering, vol.44, No.8, pp.2351-2363, 2016
  • X-B Li, M Oishi, M Oshima, F-C Li, S-J Li, Measuring Elasticity-induced Unstable Flow Structures in a Curved Microchannel Using Confocal Micro Particle Image Velocimetry, Experimental Thermal and Fluid Science, Vol.75, pp.118-128, 2016
  • Li, X-B., Oishi, M., Matsuo, T., Oshima, M., Li, F-C., Measurement of viscoelastic fluid flow in the curved microchannel using digital holographic microscope (DHM) and polarized camera, ASME Journal of Fluids Engineering, vol.138, Issue 9, 091401-1-091401-8, 2016
  • Toma, M., Oshima, M., Takagi, S., Decomposition and parallelization of strongly coupled fluid?structure interaction linear subsystems based on the Q1/P0 discretization, Computers and Structure, vol.173, pp.84-94, 2016
  • Kita, S., Oshima, M., Shimazaki, K., Iwai, T., Omura, S., Ono, T., Computational fluid dynamic study of nasal respiratory function before and after bimaxillary orthognathic surgery with bone trimming at the inferior edge of the pyriform aperture, Journal of oral and maxillofacial surgery, vol.74, Issue11, pp.2241-2251, 2016
  • 小林匡治, 根元洋光, 保科克行, 高木周, 大島まり,医用画像から取得した欠血管中心線の曲率と折れ率の最適化のためのPenalized Spline手法, 68巻, 3号, pp31-36, 2016

2015

  • KOBAYASHI, Masaharu, et al. “Development of an image-based modeling system to investigate evolutional geometric changes of a stent graft in an abdominal aortic aneurysm.” Circulation Journal (2015): CJ-15.
  • T.Akai, K.Hoshina, S.Yamamoto, H.Takeuchi, Y.Nemoto, M.Oshima, K.Shigematsu, T.Miyata, H.Yamauchi, M.Ono, T.Watanabe, Biomechanical Analysis of an Aortic Aneurysm Model and Its Clinical Application to Thoracic Aortic Aneurysms for Defining “Saccular” Aneurysms, Journal of the American Heart, doi: 10.1161,2015
  • K.Yokoyama, M.Oishi, M.Oshima, Development of a compact label-free small molecule measurement system using a periodically nanostructured sensor substrate, RSC Advances, DOI: 10.1039,pp.8014-8021,2015
  • K.Yokoyama, M.Oishi, M.Oshima, Development of an enhanced surface plasmon resonance sensor substrate by investigating a periodic nanohole array configuration, Journal of Applied Physics, vol. 118,23101,2015
  • F.Liang, M.Oshima, H.Huang, H.Liu, S.Takagi, Numerical Study of Cerebroarterial Hemodynamic Changes Following Carotid Artery Operation: A Comparison Between Multiscale Modeling and Stand-Alone Three-Dimensional Modeling, Journal of Biomechanical Engineering, vol.137, issue.10,2015
  • H.Zhang, N.Fujiwara, M.Kobayashi, S.Yamada, F.Liang, S.Takagi, M.Oshima, Development of a numerical method for patient-specific cerebral circulation using 1D-0D simulation of the entire cardiovascular system with SPECT data, Annals of biomedical engineering, doi:10.1007,s10439-015-1544-8,2015
  • X-B.Li, M.Oishi, M.Oshima, F-C.Li, S-J.Li, Measuring Elasticity-induced Unstable Flow Structures in a Curved Microchannel Using Confocal Micro Particle Image Velocimetry, Experimental Thermal and Fluid Science, vol.75, pp. 118-128,2015
  • Y.Ohhara, M.Oshima, T.Iwai, H.Kitajima, Y.Yajima, K.Mitsudo, A.Krdy, I.Tohnai, Investigation of blood flow in the external carotid artery and its branches with a new 0D peripheral model, BioMedical Engineering Online, doi: 10.1186,s12938-016-0133-x,2015
  • 大島まり, 血液循環系の流体力学, パリティ, vol.31(1), pp.33-35, 2015

2014

  • Shigeki Yamada, Marie Oshima, Yoshihiko Watanabe, Hideki Ogata, Kenji Hashimoto, Hidenori Miyake, Intramural location and size of arterial calcification are associated with stenosis at carotid bifurcation, European Journal of Radiology, 83, 6, 957-963, ELSEVIER
    DOI:10.1016/j.ejrad.2014.02.009, 2014.
  • Shigeki Yamada, Kenji Hashimoto, Hideki Ogata, Yoshihiko Watanabe, Marie Oshima, Hidenori Miyake, Calcification at orifices of aortic arch branches is a reliable and significant marker of stenosis at carotid bifurcation and intracranial arteries, European Journal of Radiology, 83, 2, 384-390, DOI: 10.1016/j.ejrad.2013.10.011., 2014.
  • Xiao-Bin Li, Hong-Na Zhang, Marie Oshima, Feng-Chen Li, Motion of passive scalar by elastic turbulence in curved channel flow, Advances in Mechanical Engineering, Vol. 2014, Article ID 734175, 10 pages, 2014.
  • Shigeki Yamada, Marie Oshima, Yoshihiko Watanabe & Hidenori Miyake, Arterial Location-Specific Calcification at the Carotid Artery and Aortic Arch for Chronic Kidney Disease, Diabetes Mellitus, Hypertension, and Dyslipidemia, Calcified Tissue International and Musculoskeletal Research, 95, 3, pp.267-274, DOI:10.1007/s00223-014-9891-2, 2014.
  • Masaaki Shojima, Akio Morita, Toshikazu Kimura, Marie Oshima, Taich Kin, Nobuhito Saito, Computational Fluid Dynamic Simulation of a Giant Basilar Tip Aneurysm with Eventual Rupture After Hunterian Ligation, World Neurosurgery, vol.82, 535.e5-9
    DOI:10.1016/j.wneu.2013.09.034, 2014.
  • Shigeki Yamada, Masaharu Kobayashi, Yoshihiko Watanabe, Hidenori Miyake and Marie Oshima, Quantitative Measurement of Blood Flow Volume in the Major Intracranial Arteries by Using 123I-Iodoamphetamine SPECT, Clinical Nuclear Medicine, vol.39, No.10, p.868-873
    DOI:10.1097/RLU.0000000000000555., 2014.
  • 木下晴之,松尾司,大島まり,藤井輝夫, デジタルホログラフィック顕微鏡によるリアルタイム三次元計測と流れ計測, 光技術コンタクト, Vol.52, No.7, pp.25-32, 2014.
  • 大島まり、石上雄太、早川基治, 脳動脈瘤の血行力学―血流の数値シミュレーションの現状と臨床応用への課題―, 脳神経外科ジャーナル,23号9巻,pp710-715
    DOI:10.7887/jcns.23.710

2013

  • 大島まり,計算屋と実験屋の融合,Collaboration between Experts in the Numerical and the Exprtimental Field,”計算工学, Vol18, No.2, p.2919″,2013.04.30
  • 大島まり、小林匡治,予測診断を目指した医用画像に基づく血流シミュレーション,Image-Based Modeling and Simulation for Predictive Medicine,”日本画像学会誌, Vol.52, No.3, pp.212-218

2012

  • Marie Oshima, Ryo Torii, Shigefumi Tokuda, Shigeki Yamada, Akio Koizumi, “Patient-Specific Modeling and Multi-Scale Blood Simulation for Computational Hemodynamic Study on the Human Cerebrovascular System”, Current Pharmaceutical Biotechnology, Vol.13, No.11, pp.2153-2165, 2012.
  • Masamichi Oishi, Koji Utsubo, Haruyuki Kinoshita, Teruo Fujii and Marie Oshima, “Continuous and Simultaneous Measurement of the Tank-Treading Motion of Red Blood Cells and Surrounding Flow Using Translational Confocal Micro-Particle Image Velocimetry (Micro-PIV) with Sub-Micron Resolution”, Measurement Science and Technology, vol.23, No.3, 2012, doi:10.1088/0957-33/23/3/035301.
  • Marie Oshima, Ryo Torii, Shigefumi Tokuda, Shigeki Yamada, Akio Koizumi, “Patient-Specific Modeling and Multi-Scale Blood Simulation for Computational Hemodynamic Study on the Human Cerebrovascular System”, Current Pharmaceutical Biotechnology, 13 (11) 2153 – 2165. PMID:22335478, Bentham Science Publishers, 2012.
  • Ryo Torii, Marie Oshima, “An integrated geometric modelling framework for patient-specific computational haemodynamic study on wide-ranged vascular network”, Computer Methods in Biomechanics and Biomedical Engineering, Vol. 15, No. 6, pp.615-625, 2012.
  • Xiao-Bin Li, Feng-Chen Li, Juan-Cheng Yang, Haruyuki Kinoshita, Masamichi Oishi and Marie Oshima, “Study on the mechanism of droplet formation in T-junction microchannel”, Chemical Engineering Science, Vol.69 (2012), pp.340-351.
  • Feng-Chen Li, Hong-Na Zhang, Yang Cao, Tomoaki Kunugi, Haruyuki Kinoshita, Marie Oshima, “A purely lastic instability and mixing enhancement in 3D curvilinear channel flow”, Chinese Physics Letters 29(9) (2012) 094704-1-094704-5.
  • Akter Hossain, Nobuyuki Oshima, Yuji Nakamura, Marie Oshima, “Numerical Simulation of Flame Dynamics Associated with Negative Velocity Induced by Deformed Flame Shape”, Combustion Theory and Modelling, Vol.16, No.5, pp.799-816.
  • 大島まり, “ステントによる血流障害のレオロジー”, International Review of Thrombosis, Vol.7, No.1, pp.33-38.
  • 大島まり, “血管障害における流体力学的アプローチの果たす役割〈Ⅰ〉”, Angiology Frontier, Vol.11, No.2, pp.2-5.
  • 大島まり, “血管障害における流体力学的アプローチの果たす役割〈Ⅱ〉 -in vivo シミュレーションを目指した試み-“, Angiology Frontier, Vol.11, No.3, pp.1-5.

2011

  • Oishi M, Kinoshita H, Fujii T and Oshima M 2011 Simultaneous measurement of internal and surrounding flows of a moving droplet using multicolour confocal micro-particle image velocimetry (micro-PIV) Meas. Sci. Technol. 22 105401 (13pp) doi:10.1088/0957-0233/22/10/105401
  • Ryo Torii, Marie Oshima, Toshio Kobayashi, Kiyoshi Takagi, Tayfun E. Tezduyar, “Influencing Factors in Image-Based Fluid-Structure Interaction Computation of Cerebral Aneurysms”, International Journal for Numerical Methods in Fluids, Vol. 65, Issue 1-3, pp.324-340, 2011.01.

2010

  • Feng-Chen Li, H.Kinoshita, Xiao-Bin Li, M.Oishi, T.Fujii, M.Oshima, “Creation of very-low-Reynolds-number chaotic fluid motions in microchannels”, Experimental Thermal and Fluid Science 34, 2010.01
  • 大石正道,大島まり,木下晴之,藤井輝夫,小林敏雄, “多波長共焦点マイクロPIVによるマイクロ液滴生成過程の計測”, 可視化情報学会論文集,Vol.30,No.9,pp.55-64, 2010.09.
  • 武藤昌也, 坪倉誠, 大島まり, 大島伸行, “周囲に周期変動が与えられた球に負荷する流体力” 機械学会論文集B編, 76巻764号, pp.563-569, 日本機械学会, 2010.04.25

2009

  • R.Torii, M.Oshima, T.Kobayashi, K.Takagai, Tayfun E. Tezduyar, “Fluid-Structure Interaction modeling of blood flow and Cerebral Aneurysm: Significance of Artery and Aneurysm Computer Methods in Applied Mechanics and Engineering”, vol.198 (2009) pp.3613–3621,In Press (available online, doi:10.1016/j.cma.2008.08.020)
  • Torii,R., M.Oshima., Kobayashi,T., Takagi,K., Tayfun,E.Tezduyar., “Influence of wall thickness on fluid-structure interaction computations of cerebral aneurysms”, International Journal for Numerical Method in Biomedical Engineering, Published online, DOI: 10.1002/cnm.1289, 2009.
  • Torii.R., M.Oshima., Kobayashi.T., Takagi.K., Tayfun E. Tezduyar, “Role of 0D peripheral vasculature model in fluid–structure interaction modeling of aneurysms”, Computational Mechanics , available online, doi: 10.1007/s00466-009-0439-7, 2009.
  • Torii.R., M.Oshima., Kobayashi.T., Takagai.K., Tayfun E. Tezduyar, “Coupling 3D Fluid-structure Interaction Modeling of Cerebral Aneurysm with 0D Arterial Network Model as Boundary Conditions”,日本シミュレーション学会論文誌,Vol.1, No.4, pp.81-90, 2009.
  • Nagai,M., Oishi,M., M.Oshima., Asai,H., Fujita,H., “Three-Dimensional Two-Component Velocity Measurement of The Flow Field Induced by The Vorticella Picta Microorganism Using a Confocal Microparticle Image Velocimetry Technique”, Biomicrofluidics 3, 014105 (2009).
  • R.Torii, M.Oshima, T.Kobayashi, K.Takagai, Tayfun E. Tezduyar Coupling, “3D Fluid-structure Interaction Modeling of Cerebral Aneurysm with 0D Arterial Network Model as Boundary Conditions”, 日本シミュレーション学会論文誌,Vol.1,No.4,pp.81-90,2009
  • 武藤昌也, 大島まり, 大島伸行, “高粒子体積率で存在する粒子に負荷する乱流中の流体抵抗力”, 機械学会論文集B編, Vol.75, No.749, pp.61-67, 2009.

2008

  • Patient-Specific Modeling and Multi-Scale Simulation of Blood Flow in the Arterial Circle of Willis, Oshima.M., Blood and air flow modeling in complex geometries, (2008).
  • Fluid-Structure Interaction Modeling of a Patient-Specific Cerebral Aneurysm: Influence of Structural Modeling, Torii.R., Oshima.M., Kobayashi.T., Takagi.K., Tayfun.E.Tezduyar., Computational Mechanics, Vol.43, pp.151-159, 査読有(2008).
  • Fluid-Structure Interaction modeling of blood flow and Cerebral Aneurysm: Significance of Artery and Aneurysm Shapes, Torii,R., Oshima,M., Kobayashi,T., Takagi,K., Tayfun,E.Tezduyar., Computer Methods in Applied Mechanics and Engineering, published online, DOI: 10.1016/j.cma. 2008.08.020, 査読有(2008).
  • 脳動脈瘤における流体力学と数値シミュレーション的アプローチ, 大島まり, 鳥井 亮, 早川基治, 庄島正明, 高木 清, 脳神経外科速報 Vol.18, No.4, pp.462-470, 査読有(2008).
  • 循環系血流解析における末梢血管網を考慮した流出境界条件のモデリング, 徳田茂史, 杉山 聡, 畝村 毅, 大島まり, 日本機械学会論文集(B編)74巻, 740号, pp.871-878, 査読有(2008).

2007

  • R. Torii, M. Oshima, T. Kobayashi, K. Takagi, T. E.. Tezduyar, “Influence of Wall Elasticity in Patient-Specific Hemodynamic Simulations”, Computers & Fluids, Vol.36, Issue 1, pp.160-168, Elsevier, 2007.01.
  • Oishi M, Oshima M, Bando Y and Kobayashi T 2007 Time-resolved Stereo PIV Measurement of Pulsatile Flow in an Artery Model Journal of Flow Visualization and Image Processing 14 67-84
  • F.-C. Li, M. Oishi, Y. Kawaguchi, N. Oshima, M. Oshima, “Experimental Study on Symmetry Breaking in a Swirling Free-surface Cylinder Flow Influenced by Viscoelasticity”, Experimental Thermal and Fluid Science Vol.31, issue3, pp.237-248, Elsevier, 2007.01.
  • H.Kinoshita, S.Kaneda, T.Fujii, M.Oshima, “Three-Dimensional Measurement and Visualization of Internal Flow of a Moving Droplet using Confocal Micro-PIV”, Lab on a Chip, 2007, Vol.7, issue3, pp.338-346, 2007.03.
  • R. Torii, M. Oshima, T. Kobayashi, K. Takagi, T. E.. Tezduyar, “Numerical Investigation of the Effect of Hypertensive Blood Pressure on Cerebral Aneurysm-Dependence of the Effect on the Aneurysm Shape”, International Journal for Numerical Methods in Fluids, Vol. 54, Issue 6-8, pp.995-1009, 2007.04.19.

2006

  • M. Oshima, R. Torii, K. Takagi, “Image-Based Simulation of Blood Flow and Arterial Wall Interaction for Cerebral Aneurysms”, Mechanics of Biological Tissue, Springer, pp.323-335, 2006.03.
  • M. Oshima, R. Torii, “Numerical Evaluation of Elastic Models in Blood Flow-Arterial Wall Interaction”, International Journal of Computational Fluid Dynamics, Vol.20, Nos.3-4, pp.223-228, Taylor & Francis, March-May 2006.
  • R. Torii, M. Oshima, T. Kobayashi, K. Takagi, T. E.. Tezduyar, “Computer Modeling of Cardiovascular Fluid-Structure Interactions with the Deforming-Spatial-Domain/Stabilized Space-Time Formulation”, Computer Methods in Applied Mechanics and Engineering, Vol.195, Issues 13-16, pp. 1885-1895, Elsevier, 2006.02.15.
  • F.-C.Li, Y.Kawaguchi, K.Hishida, M.Oshima, “Investigation of Turbulence Structures in a Drag-reduced Turbulent Channel Flow with Surfactant Additive by Stereoscopic Particle Image Velocimetry”, Experiments in Fluids, Vol.40, No.2, pp.218-230, Springer, 2006.02.
  • 坂東佳憲, 大島まり, 大石正道, 佐賀徹雄, 小林敏雄, “実血管形状脳動脈瘤モデル内のステレオPIV計測”, 日本機械学会論文集, Vol.72, No.722, B編, pp.2386 -2393, 2006.10.
  • 新井淳, 大島伸行, 大島まり, 伊藤寿, 久保田正人, “スリットインゼクタによる乱流中への噴霧流のLES解析”, 日本機械学会論文集, Vol.72, No.724, B編, pp. -, 2006.12.
  • 大島まり, “血管病変に関する計算バイオメカニクス”, 脈管学Vol.46, No.6, pp.777-786脈管研究のための基盤テクノロジーの進歩-医薬工連携-特集号, 日本脈管学会, 2006.12.25.

2005

  • M. Shojima, M. Oshima, K. Takagi, R. Torii, K. Nagata, I. Shirouzu, A. Morita, T. Kirino, “Role of the Bloodstream Impacting Force and the Local Pressure Elevation in the Rupture of Cerebral Aneurysms”, Stroke, Vol. 36, No. 11, pp.1933-1938.
  • M. Oshima, H. Sakai, R. Torii, “Modeling of Inflow Boundary Conditions for Image-Based Simulation of Cerebrovascular Flow”, International Journal for Numerical Methods in Fluids, John Wiley & Sons, Ltd.,Vol.47, Issue6-7, PP.603-617.

2004

  • M. Oshima, “A New Approach to Cerebral Hemodynamics – Patient-Specific Modeling and Numerical Simulation of Blood Flow and Arterial Wall Interaction-”, IACM Expressions, Bulletin for The International Association for Computaional Mechanics, No.16, pp.4-9.
  • 大島まり, 高木清, 早川基治, “数値シミュレーションによる脳動脈瘤に関する血行力学的解明”, 医学物理第23巻第4号, pp.209-214.
  • 大島まり, “イメージベーストによる循環系バイオメカニクス”, 日本機械学会誌, 2004年5月号, Vol.107, No.1026, pp.45-48.
  • 大島まり, 長野京平, 鳥井亮, 高木清, 早川基治, “Image-Based Simulationによる脳血管形状の血行力学に与える影響の検討”, 日本機械学会論文集(A編), 70巻, 697号, イメージベースド連成バイオメカニクス特集号, pp.86-92.
  • 鳥井亮, 大島まり, 小林敏雄, 高木清, T.E..Tezduyar, “Image-Based 血流数値シミュレーションにおける壁面弾性の影響”, 日本機械学会論文集(A編), 70巻, 697号, イメージベースド連成バイオメカニクス特集号, pp.70-77.
  • 吉川暢宏, 安達泰治, 大島まり, 鈴木克幸, 山口隆美, “イメージベースト連成バイオメカニクスに関するわが国の研究動向”,日本機械学会論文集(A編), 70巻, 697号, イメージベースド連成バイオメカニクス特集号, pp.3-8.
  • M. Shojima, M. Oshima, K. Takagi, R. Torii, M. Hayakawa, K. Katada, A. Morita, T. Kirino, “Magnitude and Role of Wall Shear Stress on Cerebral Aneurysm: Computational Fluid Dynamic Study of 20 Middle Cerebral Artery Aneurysms”, Stroke, Vol. 35, No. 11, pp.2500-2505, American Heart Associ固定ページを表示ation, 2004.11.
  • 佐賀徹雄, 大島まり, “マイクロバイオ流”, 日本機械学会講習会 実験流体力学-マイクロ流れ実験の基礎と応用-, 2004.7.1-2,東京, No.04-14, pp.33-36 .
  • 大島まり, “イメージベースト連成バイオメカニクス解析”, 日本機械学会 バイオエンジニアリング部門報No.33, 2004.9.1, pp.6-7.

2003

2002

  • MARIE OSHIMA, TOSHIO KOBAYASHI KIYOSHI TAKAGI, “Biosimulation and Visualization Effect of Cerebrovascular Geometry on Hemodynamics”, NEW YORK Academy of Sciences , 972, pp. 337-344 .
  • 大島まり,高木 清,早川基治,小林敏雄, “脳血管内の血流数値シミュレーションと可視化”, 可視化情報学会誌,22巻85号,pp.77-81.
  • 大島まり, “脳血管障害における医用画像に基づく血流シミュレーション”, ながれ、Vol. 21, No.2, pp. 122-128.
  • 任 唯淸,小林敏雄,佐賀徹雄,大島まり, “軸流送風機まわりの三次元流れに関する研究”, ターボ機械,第30巻,第8号,pp.491-496.
  • 大島まり, “脳動脈瘤に関する医用画像からの血管形状モデリングと血流解析”, BME. Vol.16, No.8, pp.5-11.
  • 大島まり, “脳血管障害における計算バイオメカニクス”, 血管医学, Vol.3, No.5, pp.519-527.
  • 井上克哉,弘畑幹鐘,谷口伸行,大島まり, “水素拡張火炎のLESとNOx生成の予測”, 生産研究,Vol.54,1/2号, pp.71-74.

2001

  • R. Torii., M. Oshima., T. Kobayashi, K. Takagi, The Hemodynamic Study of the Cerebral Artery Using Numerical Simulations Based on Medical Imaging Data, Journal of Visualization. Vol.4. No.3. (2001). pp277-284.
  • M. Oshima., R. Torii., T. Kobayashi., N. Taniguchi., K. Takagi, Finite element simulation of blood flow in the cerebral artery, Computer Methods in Applied Mechanics and Engineering. ELSEVIER. No.191. (2001). pp661-671.
  • R. Torii., M. Oshima., T. Kobayashi, K. Takagi, Numerical Simulation System for Blood Flow in the Cerebral Artery Using CT Imaging Data, JSME International Journal. Series C, Vol.44, No.4, 2001, pp.982-989.
  • 大島まり, 計算バイオメカニクスによる血管障害のメカニズムの解明, 生産研究, 第53巻, 第3号, pp.26-28. 東京大学生産技術研究所.
  • 鳥井 亮, 大島まり, 小林敏雄, 谷口伸行, 分岐を考慮した脳血管内流れの数値解析, 生産研究, 第53巻, 第3号, pp.31-34. 東京大学生産技術研究所.
  • 大島まり, 谷口伸行, Dynamic SGSモデルによるMHD乱流の解析, 生産研究, 第53巻, 第1号, pp.45-48. 東京大学生産技術研究所.

2000

  • 大島まり, 脳動脈内を流れる血液の数値シミュレーション, 「シミュレーション」. 第19巻第2号. pp.36-39. 日本シュミレーション学会
  • 大島まり, 鳥井 亮, 高木 清, 脳動脈瘤の計算力学, Bio Medical Engineering, 第14巻,第10号, pp.14-17. 日本ME学会
  • 鳥井 亮, 大島まり, 小林敏雄, 高木 清, CT画像を利用した脳血管内流れ数値解析システムの構築, 機論B編. 第66巻第652号. pp.3041-3048. 日本機械学会
  • R. Torii., M. Oshima., T. Kobayasi, K. Takagi, Numerical Visualitation of Blood Flow in the Cerebral Artery, Journal of Visualization, Vol.3, No.3.