Differentiating Left Ventricular Remodeling in Aortic Stenosis From Systemic Hypertension

Overview

Journal Circ Cardiovasc Imaging

Specialties Cardiology & Vascular Diseases
Radiology

Date 2024 Aug 20

PMID 39163368

Authors

Masliza Mahmod

Kenneth Chan

Joao F Fernandes

Rina Ariga

Betty Raman

Ernesto Zacur

Ho-Fon Royce Law

Marzia Rigolli

Jane M Francis

Sairia Dass

Kevin OGallagher

Saul G Myerson

Theodoros D Karamitsos

Stefan Neubauer

Pablo Lamata

Affiliations

Soon will be listed here.

Abstract

Background: Left ventricular (LV) hypertrophy occurs in both aortic stenosis (AS) and systemic hypertension (HTN) in response to wall stress. However, differentiation of hypertrophy due to these 2 etiologies is lacking. The aim was to study the 3-dimensional geometric remodeling pattern in severe AS pre- and postsurgical aortic valve replacement and to compare with HTN and healthy controls.

Methods: Ninety-one subjects (36 severe AS, 19 HTN, and 36 healthy controls) underwent cine cardiac magnetic resonance. Cardiac magnetic resonance was repeated 8 months post-aortic valve replacement (n=18). Principal component analysis was performed on the 3-dimensional meshes reconstructed from 109 cardiac magnetic resonance scans of 91 subjects at end-diastole. Principal component analysis modes were compared across experimental groups together with conventional metrics of shape, strain, and scar.

Results: A unique AS signature was identified by wall thickness linked to a LV left-right axis shift and a decrease in short-axis eccentricity. HTN was uniquely linked to increased septal thickness. Combining these 3 features had good discriminative ability between AS and HTN (area under the curve, 0.792). The LV left-right axis shift was not reversible post-aortic valve replacement, did not associate with strain, age, or sex, and was predictive of postoperative LV mass regression (R=0.339, =0.014).

Conclusions: Unique remodeling signatures might differentiate the etiology of LV hypertrophy. Preliminary findings suggest that LV axis shift is characteristic in AS, is not reversible post-aortic valve replacement, predicts mass regression, and may be interpreted to be an adaptive mechanism.

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