The effect of left ventricular contractility on arterial hemodynamics: A model-based investigation

Ventricular-arterial coupling is a major determinant of cardiovascular performance, however, there are still inherent difficulties in distinguishing ventricular from vascular effects on arterial pulse phenotypes. In the present study, we employed an extensive mathematical model of the cardiovascular...

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Bibliographic Details
Published in:PloS one 2021-08, Vol.16 (8), p.e0255561-e0255561
Main Authors: Pagoulatou, Stamatia, Adamopoulos, Dionysios, Rovas, Georgios, Bikia, Vasiliki, Stergiopulos, Nikolaos
Format: Article
Language:English
Subjects:
Aorta
Arteries
Bioengineering
Biology and Life Sciences
Cardiac output
Cardiovascular research
Cardiovascular system
Contractility (Biology)
Coronary vessels
Elastic waves
Health aspects
Heart
Hemodynamics
Laboratories
Left ventricular function
Mathematical models
Medicine and Health Sciences
Middle age
Muscle contraction
Navier-Stokes equations
Phenotypes
Physical Sciences
Physiological aspects
Physiology
Pressure
Research and Analysis Methods
Simulation
Veins & arteries
Ventricle
Wave analysis
Waveforms
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Summary:Ventricular-arterial coupling is a major determinant of cardiovascular performance, however, there are still inherent difficulties in distinguishing ventricular from vascular effects on arterial pulse phenotypes. In the present study, we employed an extensive mathematical model of the cardiovascular system to investigate how sole changes in cardiac contractility might affect hemodynamics. We simulated two physiologically relevant cases of high and low contractility by altering the end-systolic elastance, E.sub.es, (3 versus 1 mmHg/mL) under constant cardiac output and afterload, and subsequently performed pulse wave analysis and wave separation. The aortic forward pressure wave component was steeper for high E.sub.es, which led to the change of the total pressure waveform from the characteristic Type A phenotype to Type C, and the decrease in augmentation index, AIx (-2.4% versus +18.1%). Additionally, the increase in E.sub.es caused the pulse pressure amplification from the aorta to the radial artery to rise drastically (1.86 versus 1.39). Our results show that an increase in cardiac contractility alone, with no concomitant change in arterial properties, alters the shape of the forward pressure wave, which, consequently, changes central and peripheral pulse phenotypes. Indices based on the pressure waveform, like AIx, cannot be assumed to reflect only arterial properties.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0255561