Pulse wave and vector flow Imaging for atherosclerotic disease progression in hypercholesterolemic swine

Non-invasive monitoring of atherosclerosis remains challenging. Pulse Wave Imaging (PWI) is a non-invasive technique to measure the local stiffness at diastolic and end-systolic pressures and quantify the hemodynamics. The objective of this study is twofold, namely (1) to investigate the capability of (adaptive) PWI to assess progressive change in local stiffness and homogeneity of the carotid in a high-cholesterol swine model and (2) to assess the ability of PWI to monitor the change in hemodynamics and a corresponding change in stiffness. Nine (n=9) hypercholesterolemic swine were included in this study and followed for up to 9 months. A ligation in the left carotid was used to cause a hemodynamic disturbance. The carotids with detectable hemodynamic disturbance showed a reduction in wall shear stress immediately after ligation (2.12 +/- 0.49 to 0.98 +/- 0.47 Pa for 40-90% ligation (Group B) and 1.82 +/- 0.25 to 0.49 +/- 0.46 Pa for >90% ligation (Group C)). Histology revealed subsequent lesion formation after 8-9 months, and the type of lesion formation was dependent on the type of the induced ligation, with more complex plaques observed in the carotids with a more significant ligation (C: >90%). The compliance progression appears differed for groups B and C, with an increase in compliance to 2.09 +/- 2.90x10(-10) m(2) Pa-1 for group C whereas the compliance of group B remained low at 8 months (0.95 +/- 0.94x10(-10) m(2) Pa-1). In summary, PWI appeared capable of monitoring a change in wall shear stress and separating two distinct progression pathways resulting in distinct compliances.

Automated summary

Non-invasive monitoring of atherosclerosis remains challenging. Pulse Wave Imaging (PW) is an effective technique to measure the stiffness of carotid arteries, analyze hemodynamics, and monitor changes over time. This study used hypercholesterolemic swine models to investigate the capabilities of PWI in assessing progressive changes in local stiffness, homogeneity of the carotid artery, and monitoring hemodynamics. The results showed that PWI can detect changes in wall shear stress and differentiate between distinct progression pathways leading to different compliances.