4D-CMR-derived E/e' using annular velocity accurately distinguished patients with echocardiography-confirmed diastolic dysfunction in the left (AUC 0.90) and right heart (AUC 0.81) (P<0.01).
Observational (n=132)
Does 4D-CMR-derived E/e' accurately detect biventricular diastolic dysfunction in patients with cardiovascular disease?
4D-CMR-derived E/e' integrating transvalvular flow and tissue velocity is a feasible and accurate tool for assessing biventricular diastolic function and detecting previously unrecognized abnormalities.
Estimación del efecto: AUC 0.90 (left heart), AUC 0.81 (right heart)
valor p: p=<0.01
Aims Cardiovascular magnetic resonance (CMR) imaging is a key modality for characterizing heart diseases, but is limited in assessing diastolic dysfunction (DD). 4D flow CMR now enables transvalvular blood flow quantification, while biventricular tissue relaxation can be quantified through annular tissue velocity and strain on standard cine images. This study investigated the utility of 4D-CMR-derived E/e' in evaluating biventricular diastolic function. Secondary aims included comparison with echocardiography to establish 4D-E/e' cutoffs for detecting unknown DD.Methods And Results Diastolic transvalvular flow (4D-E) was quantified from 4D flow in 75 controls and 57 patients with cardiovascular disease. Tissue velocity (e') was assessed using cine-derived mitral/tricuspid annular velocity, longitudinal strain rate (e'FT-SR), and strain velocity (e'FT-vel). Biventricular 4D-E/e' was feasible across all e' methods, and significantly higher in patients than controls (P < 0.05). The patients were split into two subgroups: one with echocardiographic graded DD to derive CMR cutoffs, and a second with unassessed diastolic function. 4D-E/e' using annular velocity best distinguished patients with echocardiography-confirmed DD in the left (AUC = 0.90 ± 0.05, P < 0.01) and right heart (AUC = 0.81 ± 0.07, P < 0.01). Among patients without a diastolic assessment, 71% were identified with abnormal left ventricular diastolic function and 61% with abnormal right ventricular diastolic function when stratified against the lower 4D-E/e' cutoffs.Conclusion 4D-E/e', integrating transvalvular flow and tissue velocity, is feasible for biventricular diastolic function assessment. CMR identified previously unrecognized biventricular diastolic abnormalities in patients with cardiovascular disease, suggesting 4D-E/e' may be a valuable tool for early detection and referral for further diastolic testing.
Grob et al. (Thu,) conducted a observational in Diastolic dysfunction in cardiovascular disease (n=132). 4D-CMR-derived E/e' vs. Echocardiography and healthy controls was evaluated on Distinguishing patients with echocardiography-confirmed diastolic dysfunction (AUC 0.90 (left heart), AUC 0.81 (right heart), p=<0.01). 4D-CMR-derived E/e' using annular velocity accurately distinguished patients with echocardiography-confirmed diastolic dysfunction in the left (AUC 0.90) and right heart (AUC 0.81) (P<0.01).
Synapse has enriched 5 closely related papers on similar clinical questions. Consider them for comparative context: