A nonlinear biphasic model of flow-controlled infusion in brain: Fluid transport and tissue deformation analyses

Journal of Biomechanics

Volumn 42, Issue 13, 2009, Pages 2017-2025

  Smith, Joshua H ^a   García, José Jaime ^b  

^a LAFAYETTE COLLEGE   (United States)

^b UNIVERSIDAD DEL VALLE   (Colombia)

Author keywords

Convection enhanced delivery; Finite element model; Hydraulic conductivity; Infusion; Interstitial flow

Indexed keywords

BIPHASIC; BIPHASIC MODELS; BRAIN TISSUE; COLLATERAL DAMAGE; CONSTANT FLOW RATES; CONVECTION-ENHANCED DELIVERY; DEGREE OF NON-LINEARITY; EXPERIMENTAL TEST; FINITE ELEMENT ALGORITHMS; FINITE ELEMENT MODEL; FLUID TRANSPORT; FLUID VELOCITIES; GEOMETRIC AND MATERIAL NONLINEARITIES; GEOMETRICAL NON-LINEARITY; INFUSION; INTERSTITIAL FLOW; LAGRANGIAN; LINEAR ANALYSIS; MATERIAL AND GEOMETRICAL NON-LINEARITY; MATERIAL NON-LINEARITY; MAXIMUM VALUES; NON-LINEAR BOUNDARY CONDITIONS; NONLINEAR EFFECT; NONLINEAR MATHEMATICAL MODEL; PARAMETER SET; RADIAL DISPLACEMENTS; SPHERICAL SYMMETRY; TISSUE DEFORMATIONS;

BRAIN; DEFORMATION; FLOW RATE; HYDRAULIC CONDUCTIVITY; MATHEMATICAL MODELS; NONLINEAR OPTICS; SET THEORY; STRAIN; STRESS-STRAIN CURVES; TISSUE; TRANSPORT PROPERTIES;

FINITE ELEMENT METHOD;

ARTICLE; BRAIN DAMAGE; BRAIN PERFUSION; CONTROLLED STUDY; FLOW KINETICS; FLOW RATE; FLUID FLOW; FLUID TRANSPORT; MATHEMATICAL MODEL; NONLINEAR SYSTEM; POROSITY; PRIORITY JOURNAL; STRESS STRAIN RELATIONSHIP;

ANIMALS; BIOLOGICAL TRANSPORT; BRAIN; COMPUTER SIMULATION; ELASTIC MODULUS; HARDNESS; HUMANS; INFUSIONS, PARENTERAL; INTRACRANIAL PRESSURE; MODELS, BIOLOGICAL; PHARMACEUTICAL PREPARATIONS; PHARMACOKINETICS; RHEOLOGY;

EID: 69449084511     PISSN: 00219290     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.jbiomech.2009.06.014     Document Type: Article

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