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American journal of physiology. Heart and circulatory physiology
Sep 01, 2017;313 (3): H558-H567.

Relative contributions from the ventricle and arterial tree to arterial pressure and its amplification: an experimental study.

Nicholas Gaddum, Jordi Alastruey, Phil Chowienczyk, Marcel C M Rutten, Patrick Segers, Tobias Schaeffter
Author Information
  1. Nicholas Gaddum: Division of Imaging Sciences and Biomedical Engineering, King's College London, St. Thomas' Hospital, London, United Kingdom; nickgaddum@gmail.com.
  2. Jordi Alastruey: Division of Imaging Sciences and Biomedical Engineering, King's College London, St. Thomas' Hospital, London, United Kingdom.
  3. Phil Chowienczyk: King's College London British Heart Foundation Centre, St. Thomas' Hospital, London, United Kingdom.
  4. Marcel C M Rutten: Department of Biomedical Engineering, Technische Universiteit Eindhoven, Eindhoven, The Netherlands.
  5. Patrick Segers: Ghent University, IBiTech-bioMMeda, iMinds Medical IT, Gent, Belgium; and.
  6. Tobias Schaeffter: Physikalisch-Technische Bundesanstalt, Medical Physics and Metrological Information Technology, Berlin, Germany.
PMID: 28576835 DOI: 10.1152/ajpheart.00844.2016

Abstract

Arterial pressure is an important diagnostic parameter for cardiovascular disease. However, relative contributions of individual ventricular and arterial parameters in generating and augmenting pressure are not understood. Using a novel experimental arterial model, our aim was to characterize individual parameter contributions to arterial pressure and its amplification. A piston-driven ventricle provided programmable stroke profiles into various silicone arterial trees and a bovine aorta. Inotropy was varied in the ventricle, and arterial parameters modulated included wall thickness, taper and diameter, the presence of bifurcation, and a native aorta (bovine) versus silicone. Wave reflection at bifurcations was measured and compared with theory, varying parent-to-child tube diameter ratios, and branch angles. Intravascular pressure-tip wires and ultrasonic flow probes measured pressure and flow. Increasing ventricular inotropy independently augmented pressure amplification from 17% to 61% between the lower and higher systolic gradient stroke profiles in the silicone arterial network and from 10% to 32% in the bovine aorta. Amplification increased with presence of a bifurcation, decreasing wall thickness and vessel taper. Pulse pressure increased with increasing wall thickness (stiffness) and taper angle and decreasing diameter. Theoretical predictions of wave transmission through bifurcations werre similar to measurements (correlation: 0.91, = 0.94) but underestimated wave reflection (correlation: 0.75, = 0.94), indicating energy losses during mechanical wave reflection. This study offers the first comprehensive investigation of contributors to hypertensive pressure and its propagation throughout the arterial tree. Importantly, ventricular inotropy plays a crucial role in the amplification of peripheral pressure wave, which offers opportunity for noninvasive assessment of ventricular health. The present study distinguishes contributions from cardiac and arterial parameters to elevated blood pressure and pressure amplification. Most importantly, it offers the first evidence that ventricular inotropy, an indicator of ventricular function, is an independent determinant of pressure amplification and could be measured with such established devices such as the SphygmoCor.

Keywords

arterial model arterial pressure experimental model hypertension pressure amplification pulse pressure reflection

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MeSH Term

Animals
Aorta
Arterial Pressure
Blood Flow Velocity
Cattle
Computer Simulation
Elastic Modulus
Heart Ventricles
Hypertension
Models, Anatomic
Models, Cardiovascular
Myocardial Contraction
Pulse Wave Analysis
Regional Blood Flow
Silicones
Time Factors
Transducers, Pressure
Vascular Stiffness
Ventricular Function, Left
Ventricular Pressure

Chemicals

Silicones
Journal Article
Article has an altmetric score of 2

Word Cloud

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