PT - JOURNAL ARTICLE AU - E G Caiani AU - C Corsi AU - L Sugeng AU - P MacEneaney AU - L Weinert AU - V Mor-Avi AU - R M Lang TI - Improved quantification of left ventricular mass based on endocardial and epicardial surface detection with real time three dimensional echocardiography AID - 10.1136/hrt.2005.060889 DP - 2006 Feb 01 TA - Heart PG - 213--219 VI - 92 IP - 2 4099 - http://heart.bmj.com/content/92/2/213.short 4100 - http://heart.bmj.com/content/92/2/213.full SO - Heart2006 Feb 01; 92 AB - Objective: To develop a technique for volumetric analysis of real time three dimensional echocardiography (RT3DE) data aimed at quantifying left ventricular (LV) mass and to validate the technique against magnetic resonance (MR) assumed as the reference standard. Design: RT3DE, which has recently become widely available, provides dynamic pyramidal data structures that encompass the entire heart and allows four dimensional assessment of cardiac anatomy and function. However, analysis techniques for the quantification of LV mass from RT3DE data are fundamentally two dimensional, rely on geometric modelling, and do not fully exploit the volumetric information contained in RT3DE datasets. Twenty one patients underwent two dimensional echocardiography (2DE), RT3DE, and cardiac MR. LV mass was measured from 2DE and MR images by conventional techniques. RT3DE data were analysed to semiautomatically detect endocardial and epicardial LV surfaces by the level set approach. From the detected surfaces, LV mass was computed directly in the three dimensional space as voxel counts. Results: RT3DE measurement was feasible in 19 of 21 patients and resulted in higher correlation with MR (r  =  0.96) than did 2DE (r  =  0.79). RT3DE measurements also had a significantly smaller bias (−2.1 g) and tighter limits of agreement (2SD  =  ±23 g) with MR than did the 2DE values (bias (2SD) −34.9 (50) g). Additionally, interobserver variability of RT3DE (12.5%) was significantly lower than that of 2DE (24.1%). Conclusions: Direct three dimensional model independent LV mass measurement from RT3DE images is feasible in the clinical setting and provides fast and accurate assessment of LV mass, superior to the two dimensional analysis techniques.