Modeling advection and diffusion of oxygen in complex vascular networks

A realistic geometric model for the three-dimensional capillary network geometry is used as a framework for studying the transport and consumption of oxygen in cardiac tissue. The nontree-like capillary network conforms to the available morphometric statistics and is supplied by a single arterial so...

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Bibliographic Details
Published in:Annals of biomedical engineering 2001-04, Vol.29 (4), p.298-310
Main Authors: Beard, D A, Bassingthwaighte, J B
Format: Article
Language:English
Subjects:
Advection
Animals
Biological Transport, Active
Biomedical Engineering
Blood Vessels - metabolism
Cardiovascular system
Dissolved oxygen
Finite difference method
Hemodynamics
Hemoglobin
Hypoxia
Mathematical models
Models, Biological
Models, Cardiovascular
Models, Statistical
Myocardium - metabolism
Myoglobin - metabolism
Myoglobins
Oxygen
Oxygen - metabolism
Oxygen Consumption
Physiology
Proteins
Tissue
Tissues
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Description
Summary:A realistic geometric model for the three-dimensional capillary network geometry is used as a framework for studying the transport and consumption of oxygen in cardiac tissue. The nontree-like capillary network conforms to the available morphometric statistics and is supplied by a single arterial source and drains into a pair of venular sinks. We explore steady-state oxygen transport and consumption in the tissue using a mathematical model which accounts for advection in the vascular network, nonlinear binding of dissolved oxygen to hemoglobin and myoglobin, passive diffusion of freely dissolved and protein-bound oxygen, and Michaelis-Menten consumption in the parenchymal tissue. The advection velocity field is found by solving the hemodynamic problem for flow throughout the network. The resulting system is described by a set of coupled nonlinear elliptic equations, which are solved using a finite-difference numerical approximation. We find that coupled advection and diffusion in the three-dimensional system enhance the dispersion of oxygen in the tissue compared to the predictions of simplified axially distributed models, and that no "lethal corner," or oxygen-deprived region occurs for physiologically reasonable values for flow and consumption. Concentrations of 0.5-1.0 mM myoglobin facilitate the transport of oxygen and thereby protect the tissue from hypoxia at levels near its P50, that is, when local oxygen consumption rates are close to those of delivery by flow and myoglobin-facilitated diffusion, a fairly narrow range.
ISSN:0090-6964
1573-9686
DOI:10.1114/1.1359450