One-dimensional model for propagation of a pressure wave in a model of the human arterial network: Comparison of theoretical and experimental results

Journal of Biomechanical Engineering

Volumn 133, Issue 12, 2011, Pages

  Saito, Masashi ^a   Ikenaga, Yuki ^a   Matsukawa, Mami ^a   Watanabe, Yoshiaki ^a   Asada, Takaaki ^b   Lagrée, Pierre Yves ^c  

^a DOSHISHA UNIVERSITY   (Japan)

^b MURATA MANUFACTURING CO LTD   (Japan)

^c SORBONNE UNIVERSITÉ   (France)

Author keywords

1D modeling; human arterial network; wave propagation

Indexed keywords

1-D MODELS; 1D MODELING; APPROXIMATION ERRORS; ARTERIAL MODEL; ARTERIAL NETWORKS; ARTERIAL STIFFNESS; BIFURCATION TUBE; CONTINUITY EQUATIONS; CONTROLLED PUMPS; FLEXIBLE TUBES; GOVERNING EQUATIONS; HAGEN-POISEUILLE; IN-VIVO; INCIDENT WAVES; INNER PRESSURE; MEASURED DATA; NON-LINEARITY; ONE-DIMENSIONAL MODEL; PRESSURE PROPAGATION; PRESSURE WAVES; PULSE WAVE; PULSE WAVEFORMS; SET-UPS; SQUARE SUM; THEORETICAL ESTIMATION; THEORETICAL MODELS; TUBE MODEL; TUBE WALLS; TWO-COMPONENT; ULTRASONIC DIAGNOSTICS; VISCOELASTIC TUBES;

BIFURCATION (MATHEMATICS); CONTROL NONLINEARITIES; ELASTICITY; HEMODYNAMICS; NAVIER STOKES EQUATIONS; VISCOSITY; WAVE PROPAGATION;

TUBES (COMPONENTS);

POLYURETHAN; BIOMIMETIC MATERIAL; POLYMER;

ACCURACY; ARTICLE; ATTENUATION; FLOW RATE; HEART VENTRICLE EJECTION TIME; HUMAN; NONLINEAR SYSTEM; PULSATILE FLOW; PULSE WAVE; THEORETICAL MODEL; ULTRASOUND; VALIDITY; YOUNG MODULUS; ARTERY; BIOLOGICAL MODEL; BLOOD PRESSURE; CHEMISTRY; COMPARATIVE STUDY; HYDRODYNAMICS; PHYSIOLOGY; REPRODUCIBILITY; VISCOSITY;

ARTERIES; BIOMIMETIC MATERIALS; BLOOD PRESSURE; HUMANS; HYDRODYNAMICS; MODELS, BIOLOGICAL; POLYMERS; REPRODUCIBILITY OF RESULTS; VISCOSITY;

EID: 84855217098     PISSN: 01480731     EISSN: 15288951     Source Type: Journal    
DOI: 10.1115/1.4005472     Document Type: Article

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