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Comparison of Echocardiographic and Electrocardiographic Mapping for Cardiac Resynchronisation Therapy Optimisation

Research output: Contribution to journalArticle

Original languageEnglish
JournalCardiology Research and Practice
Accepted/In press14 Nov 2018

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Abstract

ABSTRACT Study hypothesis: We sought to investigate the association between echocardiographic optimisation and ventricular activation time in cardiac resynchronization therapy (CRT) patients, obtained through the use of electrocardiographic mapping (ECM). We hypothesised that echocardiographic optimisation of the pacing delay between the atrial and ventricular leads - atrio-ventricular delay (AVD) and the delay between ventricular leads - inter-ventricular pacing interval (VVD) would correlate with reductions in ventricular activation time. Background: Optimisation of AVD and VVD may improve CRT patient outcome. Optimal delays are currently set based on echocardiographic indices; however, acute studies have found that reductions in bulk ventricular activation time correlate with improvements in acute haemodynamic performance. Materials and methods: Twenty-one patients with established CRT criteria were recruited. After implantation, patients underwent echo-guided optimisation of the AVD and VVD. During this procedure, the participants also underwent non-invasive ECM. ECM maps were constructed for each AVD and VVD. ECM maps were analysed offline. Total ventricular activation time (TVaT) and a ventricular activation time index (VaT10-90) were calculated to identify the optimal AVD and VVD timings that gave the minimal TVaT and VaT10-90 values. We correlated cardiac output with these electrical timings. Results: Echocardiographic programming optimisation was not associated with the greatest reductions in biventricular activation time (VaT10-90 and TVaT). Instead, bulk activation times were reduced by a further 20% when optimised with ECM. A significant inverse correlation was identified between reductions in bulk ventricular activation time and improvements in LVOT VTI (p<0.001), suggesting that improved ventricular hemodynamics are a sequelae of more rapid ventricular activation. Conclusions: EAM guided programming optimisation may achieve superior fusion of activation wave fronts leading to improvements in CRT response.

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