Interaction between adenosine and flow-induced dilation in coronary
microvascular network.
Liao, James C., and Lih Kuo.
Department of Chemical Engineering, and Department of Medical
Physiology, Microcirculation Research Institute, Texas A&M
University, College Station, Texas 77843-01114
APStracts 3:0514H, 1996.
Previous studies have demonstrated that coronary microvessels are
regulated by at least three possible means: the metabolite-induced,
shear-induced, and pressure-induced (myogenic) mechanisms. Adenosine,
a putative metabolic vasodilator, preferentially dilates downstream
coronary microvessels; whereas the shear-sensitive mechanism is
detected predominantly in upstream larger microvessels. However, the
interaction of these mechanisms and the significance of the
heterogeneous vascular responsiveness in flow regulation have not
been evaluated. These tasks cannot be performed experimentally
because of several confounding factors that cannot be separated.
Therefore, the present study employed a data-based modeling approach
to investigate the role of response heterogeneity in a coronary
vascular network and to test the hypothesis that shear-sensitive
mechanism or the myogenic mechanisms will enhance the vascular
sensitivity to adenosine due to the heterogeneity of the vascular
responsiveness. We obtained necessary data and developed empirical
models for the responsiveness of single vessels to pressure, shear
stress, and adenosine. With the single-vessel models, a network model
was established based on the branching pattern of coronary
microvessels, mass balance, and fluid mechanics laws. Model
simulation predicted an enhanced vascular response to adenosine in
the network. Such an enhancement is caused by the heterogeneous
vascular response to adenosine and the predominant flow-induced
dilation in the large arterioles. Preferential dilation of the
downstream small arterioles to adenosine initiates an increase in
flow and a decrease in pressure at upstream vessels. The increased
flow activates the shear-sensitive mechanism of the upstream large
arterioles and further enhances the flow. This hemodynamic
interaction contributes up to about 20% of the adenosine-induced flow
increase and also reduces the adenosine-induced pressure drop. In
contrast to the shear-sensitive mechanism, myogenic response
contributes relatively little to the vascular response to adenosine.
These results suggest that various vascular regulation mechanisms and
the response heterogeneity of vessels of different sizes may act in
an integrative fashion for the optimal control of microvascular
perfusion.
Received 25 July 1996; accepted in final form 24 October 1996.
APS Manuscript Number H667-6.
Article publication pending Am. J. Physiol. (Heart Circ. Physiology).
ISSN 1080-4757 Copyright 1996 The American Physiological Society.
Published in APStracts on 31 December 1996