Multiphasic Mixture Modeling and Simulation of Coronary Circulation

2007 Fiscal Year Final Research Report Summary

• Project/Area Number: 18360054
• Research Category: Grant-in-Aid for Scientific Research (B)
• Allocation Type: Single-year Grants
• Section: 一般
• Research Field: Materials/Mechanics of materials
• Research Institution: Kyushu University
• Principal Investigator: CHEN Xian Kyushu University, Digital Medicine Initiative, Professor (70313012)
• Co-Investigator(Kenkyū-buntansha): SUGIURA Seiryo The University of Tokyo, School of Frontier Sciences, Professor (10272551)
• Project Period (FY): 2006 – 2007
• Keywords: Coronary Circulation / Mixture Theory / Finite Element Method / Biomechanics / Bio-material Modeling

Research Abstract

In this research, based on the multiphasic mixture theory, a hierarchical coronary theoretical model is proposed for the coronary system, in which the vessels have tree structure gradually bifurcating from artery and vein to capillary bed, by treating the myocardial matrix as solid phase and blood in each hierarchy of the vessel tree as specific fluid phase. Furthermore, the incompressible condition of the solid and fluid phases was imposed by applying Lagrange multiplier method. The residual weighted method was introduced for finite element formulation and followed by the descritization. The tangential stiffness matrix was derived for iterative computation of the nonlinear problems. Since the fluid variables have large degrees of freedom at a node due to the hierarchy structure, for the computational efficiency, the finite element equations were reformulated by adopting pressure as nodal variable instead of the relative velocity of fluid phase. The formulation was implemented into a home-made program and built in a multi-scale and multi-physics heart simulator. The numerical examples show that the characteristic predominate wave form of arteries (or veins) blood flow in diastolic (or systolic) can be represented by applying the proposed model and thus suggest the usability in the clinical application. It is expected that the effect of the myocardial contraction on the intramyocardial pressure and furthermore on the blood perfusion in coronary system can be elucidated by applying the proposed approach and to make contribution to etiology elucidation of the ischemic heart disease and diagnostic treatment.

Research Products

• [Presentation] 多孔質超弾性理論に基づく冠循環系と左右両心室の流体構造連成解析 (2006)
  • Author(s): 渡邉 浩志, 陳 媛, 陳 献, 他3名
  • Organizer: 第19回計算力学講演会
  • Place of Presentation: 名古屋
  • Year and Date: 20061100
  • Description: 「研究成果報告書概要(和文)」より
• [Presentation] Fluid-Structure Interaction Analysis of Left and Right Ventricles with Coronary Circulation Based on Porohyperelastic Theory (2006)
  • Author(s): Watanabe, H., Chen, Y., Chen, X., Washio, T., Sugiura, S., Hisada, T
  • Organizer: JSME 18th Computational Mechanics Conference, Nagoya
  • Year and Date: 20061100
  • Description: 「研究成果報告書概要(欧文)」より
• [Presentation] 多孔質超弾性理論に基づく冠循環血流動態の有限要素解析 (2006)
  • Author(s): 陳 媛, 陳 献, 他4名
  • Organizer: 第55回理論応用力学講演会
  • Place of Presentation: 京都
  • Year and Date: 20060500
  • Description: 「研究成果報告書概要(和文)」より
• [Presentation] Finite Element Analysis on the Hemodynamics of Coronary Circulation Based on Porohyperelastic Theory (2006)
  • Author(s): Chen, Y., Chen, X., Watanabe, H., Washio, T., Sugiura, S., Hisada, T
  • Organizer: The 55th National Congress of Theoretical and Applied Mechanics, Kyoto
  • Year and Date: 20060100
  • Description: 「研究成果報告書概要(欧文)」より