4D-Flow MRI Intracardiac Flow Analysis Considering Different Subtypes of Pulmonary Hypertension

Overview

Journal Pulm Circ

Publisher Wiley

Specialty Pulmonary Medicine

Date 2023 Nov 9

PMID 37941938

Authors

Michael T Cain

Michal Schafer

Lexie K Ross

David D Ivy

Max B Mitchell

Brett E Fenster

Todd M Bull

Alex J Barker

Daniel Vargas

Jordan R H Hoffman

Affiliations

Soon will be listed here.

Abstract

Intracardiac flow hemodynamic patterns have been considered to be an early sign of diastolic dysfunction. In this study we investigated right ventricular (RV) diastolic dysfunction between patients with pulmonary arterial hypertension (PAH) and pulmonary hypertension with chronic lung disease (PH-CLD) via 4D-Flow cardiac MRI (CMR). Patients underwent prospective, comprehensive CMR for function and size including 4D-Flow CMR protocol for intracardiac flow visualization and analysis. RV early filling phase and peak atrial phase vorticity (E-vorticity and A-vorticity) values were calculated in all patients. Patients further underwent comprehensive Doppler and tissue Doppler evaluation for the RV diastolic dysfunction. In total 13 patients with PAH, 15 patients with PH-CLD, and 10 control subjects underwent the 4D-Flow CMR and echocardiography evaluation for RV diastolic dysfunction. Reduced E-vorticity differentiated PAH and PH-CLD from healthy controls (both < 0.01) despite the same Doppler E values. E-vorticity was further decreased in PAH patients when compared to PH-CLD group ( < 0.05) with similar Doppler and tissue Doppler markers of diastolic dysfunction. A-vorticity was decreased in both PAH and PH-CLD groups compared to controls but with no difference between the disease groups. E-vorticity correlated with ejection fraction ( = 0.60, < 0.001), end-systolic volume ( = 0.50, = 0.001), stroke volume ( = 0.42, = 0.007), and cardiac output ( = 0.30, = 0.027). Intracardiac flow analysis using 4D-Flow CMR derived vorticity is a sensitive method to differentiate diastolic dysfunction in patients with different PH etiology and similar Doppler echocardiography profile.

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