• YZβ discontinuity capturing fo...

Result: YZβ discontinuity capturing for advection-dominated processes with application to arterial drug delivery

Title:
YZβ discontinuity capturing for advection-dominated processes with application to arterial drug delivery
Authors:
BAZILEVS, Y, CALO, V. M, TEZDUYAR, T. E, HUGHES, T. J. R
Source:
Stabilized, multiscale and multiphysics methodsInternational journal for numerical methods in fluids. 54(6-8):593-608
Publisher Information:
Chichester: Wiley, 2007.
Publication Year:
2007
Physical Description:
print, 37 ref
Original Material:
INIST-CNRS
Subject Terms:
Mechanics acoustics, Mécanique et acoustique, Sciences exactes et technologie, Exact sciences and technology, Physique, Physics, Domaines classiques de la physique (y compris les applications), Fundamental areas of phenomenology (including applications), Mécanique des fluides, Fluid dynamics, Méthodes de calcul en mécanique des fluides, Computational methods in fluid dynamics, Sciences biologiques et medicales, Biological and medical sciences, Sciences medicales, Medical sciences, Pharmacologie. Traitements medicamenteux, Pharmacology. Drug treatments, Pharmacologie générale, General pharmacology, Technologie pharmaceutique. Industrie pharmaceutique, Pharmaceutical technology. Pharmaceutical industry, Artère coronaire, Coronaries, B spline, B splín, Equation Navier Stokes, Navier-Stokes equations, Equation advection diffusion, Advection diffusion equation, Ecuación advección difusión, Fluide compressible, Compressible fluid, Fluido compresible, Modélisation, Modelling, Mécanique fluide numérique, Computational fluid dynamics, Simulation numérique, Digital simulation, Système administration médicament, Drug delivery systems, Vaisseau sanguin, Blood vessels, advection-diffusion equation, discontinuity capturing, drug delivery, fluids, interior layers, isogeometric analysis
Time:
4711
Document Type:
Conference Conference Paper
File Description:
text
Language:
English
Author Affiliations:
Institute for Computational Engineering and Sciences, The University of Texas at Austin, 201 East 24th Street, 1 University Station C0200, Austin, TX 78712, United States
Mechanical Engineering, Rice University, MS 321, 6100 Main Street, Houston, TX 77005, United States
ISSN:
0271-2091
Access URL:
http://pascal-francis.inist.fr/vibad/index.php?action=search&terms=18888636
Rights:
Copyright 2007 INIST-CNRS
CC BY 4.0
Sauf mention contraire ci-dessus, le contenu de cette notice bibliographique peut être utilisé dans le cadre d’une licence CC BY 4.0 Inist-CNRS / Unless otherwise stated above, the content of this bibliographic record may be used under a CC BY 4.0 licence by Inist-CNRS / A menos que se haya señalado antes, el contenido de este registro bibliográfico puede ser utilizado al amparo de una licencia CC BY 4.0 Inist-CNRS
Notes:
General pharmacology

Physics: fluid mechanics
Accession Number:
edscal.18888636
Database:
PASCAL Archive

Further Information

The YZβ discontinuity-capturing operator, recently introduced in (Encyclopedia of Computational Mechanics, Vol. 3, Fluids. Wiley: New York, 2004) in the context of compressible flows, is applied to a time-dependent, scalar advection-diffusion equation with the purpose of modelling drug delivery processes in blood vessels. The formulation is recast in a residual-based form, which reduces to the previously proposed formulation in the limit of zero diffusion and source term. The NURBS-based isogeometric analysis method, proposed by Hughes et al. (Comput. Methods Appl. Mech. Eng. 2005; 194:4135-4195), was used for the numerical tests. Effects of various parameters in the definition of the FZβ operator are examined on a model problem and the better performer is singled out. While for low-order B-spline functions discontinuity capturing is necessary to improve solution quality, we find that high-order, high-continuity B-spline discretizations produce sharp, nearly monotone layers without the aid of discontinuity capturing. Finally, we successfully apply the YZβ approach to the simulation of drug delivery in patient-specific coronary arteries.