Theoretical modeling of fluid flow in cellular biological media: An overview

Mathematical Biosciences

Volumn 225, Issue 2, 2010, Pages 83-93

  Kapellos, George E ^a   Alexiou, Terpsichori S ^a,b   Payatakes, Alkiviades C ^a,b,c  

^a UNIVERSITY OF PATRAS   (Greece)

^b INSTITUTE OF CHEMICAL ENGINEERING SCIENCES   (Greece)

^c INSTITUTE OF COMPUTER SCIENCE   (Greece)

Author keywords

Biofilm; Fluid structure interactions; Hierarchical multiscale modeling; Hydraulic permeability; Material properties; Tissue

Indexed keywords

ANISOTROPIC MICROSTRUCTURES; BIOLOGICAL MEDIA; CONFORMATIONAL CHANGE; CONSTITUENT PHASIS; CURRENT STATUS; DYNAMIC MATERIALS; EQUATION-FREE; EXPERIMENTAL OBSERVATION; EXTRACELLULAR MATRICES; FLUID FLOW; GOVERNING EQUATIONS; HYDRAULIC PERMEABILITY; MACROSCOPIC MATERIALS; MATERIAL PROPERTIES; MATERIAL PROPERTY; MIXTURE THEORY; MOMENTUM TRANSPORTS; MULTI-SCALE MODELING; MULTISCALES; NOVEL PROCESS; STRUCTURAL HIERARCHIES; THEORETICAL MODELING; TOPOLOGICAL FEATURES; UPSCALING METHODS; VOLUME-AVERAGING;

BIOFILMS; CAPILLARITY; COMPUTER SIMULATION; FLOW OF FLUIDS; FLUID STRUCTURE INTERACTION; FLUIDS; HYDRAULICS; MATERIALS PROPERTIES; MATHEMATICAL MODELS; MOMENTUM TRANSFER; STRUCTURAL PROPERTIES;

BIOLOGICAL MATERIALS;

POLYMER;

BIOFILM; COMPUTER SIMULATION; FLUID FLOW; MOMENTUM TRANSFER; NUMERICAL MODEL; PERMEABILITY; TOPOLOGY; UPSCALING;

ANISOTROPY; BIOFILM; CONFOCAL LASER MICROSCOPY; CULTURE MEDIUM; EXTRACELLULAR MATRIX; FLUID FLOW; GEOMETRY; MATHEMATICAL MODEL; MULTIPLE REGRESSION; OSTEOBLAST; REVIEW; SCALE UP; THEORETICAL MODEL; VISCOELASTICITY; WATER CONTENT;

ANIMALS; BIOFILMS; BIOLOGICAL TRANSPORT; CELL PHYSIOLOGICAL PHENOMENA; EXTRACELLULAR FLUID; EXTRACELLULAR MATRIX; HUMANS; MODELS, BIOLOGICAL;

EID: 77952671214     PISSN: 00255564     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.mbs.2010.03.003     Document Type: Review

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