Non-invasive assessment by B-mode ultrasound of arterial pulse wave intensity and its modification during ventricular dysfunction

TL;DR

This paper introduces a novel non-invasive ultrasound method to assess arterial pulse wave properties, correlating well with invasive measurements and showing potential for clinical applications like heart failure monitoring.

Contribution

The study presents a new ultrasound-based technique for non-invasively measuring arterial pulse wave velocity and wave intensity, validated against invasive methods and applicable in humans.

Findings

The ultrasound method accurately tracks wave properties in rabbit aortas.

It detects changes during ventricular dysfunction comparable to invasive methods.

Application in a human subject shows potential for clinical use.

Abstract

Arterial pulse waves contain clinically useful information: their intensity varies with cardiac performance, their speed (pulse wave velocity; PWV) depends on arterial stiffness and their reflection is affected by conduit artery tone. Here we demonstrate a novel method for non-invasively assessing wave properties. The analysis was based on changes in blood flow velocity and arterial wall diameter during the cardiac cycle. Velocity and diameter were determined by tracking the movement of speckles in successive B-mode ultrasound images acquired at high temporal frequency with an ultrafast plane-wave scanner. Blood speckle was detected in the absence of contrast agents by using singular value decomposition, and it was processed by cross-correlation techniques that correct biases in ultrasound imaging velocimetry. Results obtained in the rabbit aorta were compared with a conventional analysis based on blood velocity and pressure, employing measurements obtained with an intra-arterial catheter. The catheter-based measurements had a poorer frequency response and greater lags but patterns of forward and backward travelling waves were consistent between the conventional and new methods. Errors in PWV were also similar in magnitude, although opposite in direction. Comparable reductions in wave intensity and delays in wave arrival were detected by the two methods when ventricular dysfunction was induced pharmacologically. The non-invasive method was applied to the carotid artery of a healthy human subject and gave a PWV and patterns of wave intensity that were consistent with earlier measurements. The new system may have clinical utility, for example in screening for, and monitoring of, heart failure.