How blood flow is regulated, i.e., how perfusion is matched to tissue demands, is a central question in cardiovascular biology. The overall objective of the proposed studies is to develop quantitative theoretical models for oxygen transport and blood flow regulation in microvascular networks of skeletal muscle. The models will clarify the roles of mechanisms that coordinate changes in vascular resistance, will provide a rational structure for interpreting experimental data, and may suggest new therapeutic approaches for controlling tissue perfusion.
The specific aims are:1. To develop theoretical models to predict distributions of vascular tone in microvascular networks of skeletal muscle. Equations will be developed to describe the dependence of vascular tone on metabolic factors, wall shear stress, pressure and conducted responses in vessel walls. These equations, combined with those of network hemodynamics, will be solved to predict tone and internal diameter of each segment.2. To combine theoretical models for oxygen transport with models for flow regulation, to describe how microvascular networks regulate flow in response to changes in oxygen demand. Theoretical simulations of oxygen transport in resting skeletal muscle will be developed based on observed network structures. Models for working muscle will be developed that take into account the organization of muscle fibers into motor units.3. To develop theoretical predictions of the relationship between whole-organ oxygen demand and perfusion in skeletal muscle, based on microvascular-level oxygen transport and flow regulation processes. Results obtained in aims 1 and 2 will be used to predict variation ofmacroscopic variables (flow, consumption, extraction, tissue oxygen level) with demand.In all these studies, particular emphasis will be placed on detailed comparisons of model predictions with experimental observations. This will be facilitated by the investigator's longstanding and close collaboration with experimental physiologists.

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
5R01HL070657-03
Application #
6746049
Study Section
Cardiovascular and Renal Study Section (CVB)
Program Officer
Goldman, Stephen
Project Start
2002-05-03
Project End
2006-04-30
Budget Start
2004-05-01
Budget End
2005-04-30
Support Year
3
Fiscal Year
2004
Total Cost
$113,625
Indirect Cost
Name
University of Arizona
Department
Physiology
Type
Schools of Medicine
DUNS #
806345617
City
Tucson
State
AZ
Country
United States
Zip Code
85721
Rasmussen, Peter M; Smith, Amy F; Sakadži?, Sava et al. (2017) Model-based inference from microvascular measurements: Combining experimental measurements and model predictions using a Bayesian probabilistic approach. Microcirculation 24:
Lücker, Adrien; Secomb, Timothy W; Weber, Bruno et al. (2017) The relative influence of hematocrit and red blood cell velocity on oxygen transport from capillaries to tissue. Microcirculation 24:
Gagnon, Louis; Smith, Amy F; Boas, David A et al. (2016) Modeling of Cerebral Oxygen Transport Based on In vivo Microscopic Imaging of Microvascular Network Structure, Blood Flow, and Oxygenation. Front Comput Neurosci 10:82
Secomb, Timothy W (2016) A Green's function method for simulation of time-dependent solute transport and reaction in realistic microvascular geometries. Math Med Biol 33:475-494
Secomb, Timothy W (2015) Krogh-cylinder and infinite-domain models for washout of an inert diffusible solute from tissue. Microcirculation 22:91-8
Smith, Amy F; Secomb, Timothy W; Pries, Axel R et al. (2015) Structure-based algorithms for microvessel classification. Microcirculation 22:99-108
Roy, Tuhin K; Secomb, Timothy W (2014) Theoretical analysis of the determinants of lung oxygen diffusing capacity. J Theor Biol 351:1-8
Roy, Tuhin K; Secomb, Timothy W (2014) Functional sympatholysis and sympathetic escape in a theoretical model for blood flow regulation. Front Physiol 5:192
Buerk, Donald G; Hirai, Daniel M; Roseguini, Bruno T et al. (2014) Commentaries on viewpoint: A paradigm shift for local blood flow regulation. J Appl Physiol (1985) 116:706-7
Fry, Brendan C; Roy, Tuhin K; Secomb, Timothy W (2013) Capillary recruitment in a theoretical model for blood flow regulation in heterogeneous microvessel networks. Physiol Rep 1:e00050

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