Myocardial Perfusion: Characteristics of Distal Intramyocardial Arteriolar Trees

A combination of experimental, theoretical, and imaging methodologies is used to examine the hierarchical structure and function of intramyocardial arteriolar trees in porcine hearts to provide a window onto a region of myocardial microvasculature which has been difficult to fully explore so far. A...

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Bibliographic Details
Published in:Annals of biomedical engineering 2015-11, Vol.43 (11), p.2771-2779
Main Authors: Zamir, Mair, Vercnocke, Andrew J., Edwards, Phillip K., Anderson, Jill L., Jorgensen, Steven M., Ritman, Erik L.
Format: Article
Language:English
Subjects:
Animals
Arterioles - physiology
Biochemistry
Biological and Medical Physics
Biomedical and Life Sciences
Biomedical Engineering and Bioengineering
Biomedicine
Biophysics
Blood vessels
Classical Mechanics
Coefficient of variation
Coronary Circulation - physiology
Coronary Vessels - diagnostic imaging
Coronary Vessels - physiology
Flow rate
Heart - diagnostic imaging
Heart - physiology
Heterogeneity
Microvessels - diagnostic imaging
Microvessels - physiology
Myocardium
Power law
Segments
Shear stress
Swine
Three dimensional
Trees
X-Ray Microtomography
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Summary:A combination of experimental, theoretical, and imaging methodologies is used to examine the hierarchical structure and function of intramyocardial arteriolar trees in porcine hearts to provide a window onto a region of myocardial microvasculature which has been difficult to fully explore so far. A total of 66 microvascular trees from 6 isolated myocardial specimens were analyzed, with a cumulative number of 2438 arteriolar branches greater than or equal to 40  μ m lumen diameter. The distribution of flow rates within each tree was derived from an assumed power law relationship for that tree between the diameter of vessel segments and flow rates that are consistent with that power law and subject to conservation of mass along hierarchical structure of the tree. The results indicate that the power law index increases at levels of arteriolar vasculature closer to the capillary level, consistent with a concomitant decrease in shear stress acting on endothelial tissue. These results resolve a long standing predicament which could not be resolved previously because of lack of data about the 3D, interconnected, arterioles. In the context of myocardial perfusion, the results indicate that the coefficient of variation of flow rate in pre-capillary distal arterioles is high, suggesting that heterogeneity of flow rate in these arterioles is not entirely random but may be due at least in part to active control.
ISSN:0090-6964
1573-9686
DOI:10.1007/s10439-015-1325-4