Influence of segmented vessel size due to limited imaging resolution on coronary hyperemic flow prediction from arterial crown volume

Computational predictions of the functional stenosis severity from coronary imaging data use an allometric scaling law to derive hyperemic blood flow (Q) from coronary arterial volume (V), Q = αV(β) Reliable estimates of α and β are essential for meaningful flow estimations. We hypothesize that the...

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Bibliographic Details
Published in:American journal of physiology. Heart and circulatory physiology 2016-04, Vol.310 (7), p.H839-H846
Main Authors: van Horssen, P, van Lier, M G J T B, van den Wijngaard, J P H M, VanBavel, E, Hoefer, I E, Spaan, J A E, Siebes, M
Format: Article
Language:English
Subjects:
Animals
Cardiac Imaging Techniques - methods
Coronary vessels
Coronary Vessels - pathology
Coronary Vessels - physiopathology
Dogs
Exercise
Hemodynamics
Hyperemia - pathology
Hyperemia - physiopathology
Limit of Detection
Medical imaging
Models, Cardiovascular
Optical Imaging - methods
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Summary:Computational predictions of the functional stenosis severity from coronary imaging data use an allometric scaling law to derive hyperemic blood flow (Q) from coronary arterial volume (V), Q = αV(β) Reliable estimates of α and β are essential for meaningful flow estimations. We hypothesize that the relation between Q and V depends on imaging resolution. In five canine hearts, fluorescent microspheres were injected into the left anterior descending coronary artery during maximal hyperemia. The coronary arteries of the excised heart were filled with fluorescent cast material, frozen, and processed with an imaging cryomicrotome to yield a three-dimensional representation of the coronary arterial network. The effect of limited image resolution was simulated by assessing scaling law parameters from the virtual arterial network at 11 truncation levels ranging from 50 to 1,000 μm segment radius. Mapped microsphere locations were used to derive the corresponding relative Q using a reference truncation level of 200 μm. The scaling law factor α did not change with truncation level, despite considerable intersubject variability. In contrast, the scaling law exponent β decreased from 0.79 to 0.55 with increasing truncation radius and was significantly lower for truncation radii above 500 μm vs. 50 μm (P< 0.05). Hyperemic Q was underestimated for vessel truncation above the reference level. In conclusion, flow-crown volume relations confirmed overall power law behavior; however, this relation depends on the terminal vessel radius that can be visualized. The scaling law exponent β should therefore be adapted to the resolution of the imaging modality.
ISSN:0363-6135
1522-1539
DOI:10.1152/ajpheart.00728.2015