Faculty Bibliography

Over the past decade, catheter based treatments of an increasing variety of cardiac diseases have expanded dramatically. These advancements became available through new developments and improvements in available devices, as well as increasing expertise of operators. However, arguably it is the innovation and progress in imaging techniques, and in particular in echocardiography, that allowed for such a surge in available percutaneous procedures. In this paper, current echocardiographic techniques, imaging protocols and recommendations will be reviewed and clinical examples will be shown to illustrate the use and importance of echocardiographic imaging in catheter based procedures for structural heart disease.

Paravalvular leak (PVL) is an uncommon yet serious complication associated with surgical prosthetic valve implantation. Paravalvular leak can have significant clinical consequence such as congestive heart failure, haemolytic anaemia, and infective endocarditis. Recently, transcatheter therapy has been applied to the treatment of this disorder with reasonable procedural and clinical success. This review discusses the current state of PVLs, the utilization of multi-modality imaging in their diagnosis and treatment, and the available therapeutic options. Further aim of this review is to examine transcatheter therapy of PVLs including the principles, outcomes, and procedural-related complications.

BACKGROUND: Assessing left ventricular function is a common indication for echocardiography. It generally requires expert echocardiographer estimation and is somewhat subjective and prone to reader discordance. Mitral annular plane systolic excursion (MAPSE) has been suggested as a surrogate measurement for left ventricular function. The aim of this study was to examine the accuracy of MAPSE for predicting left ventricular ejection fraction (EF) on the basis of a large cohort of consecutive echocardiograms. METHODS: The study design was a retrospective analysis of 600 two-dimensional echocardiographic studies performed in a single laboratory. MAPSE measurement was performed by an untrained observer and compared with the EF as determined by an expert echocardiographer. The first 300 studies served as a calibration cohort to establish an algorithm for predicting EF on the basis of MAPSE measurement. The following 300 studies served as a verification cohort to test the accuracy of the established algorithm. RESULTS: Using the first 300 studies, an algorithm was developed to predict EF. Cutoff values for normal EF (>/=11 mm for women and >/=13 mm for men) and severely reduced EF (<6 mm for men and women) were identified. For the intermediate-range MAPSE values, a gender-specific regression equation was calculated to generate a predicted EF. Using this algorithm, predicted EFs were determined for the 300 patients in the verification cohort. By comparing the predicted EF and the expert-reported EF, positive and negative predictive values, sensitivity (73%-92%), specificity (81%-100%), and accuracy (82%-86%) of MAPSE for predicting EF were calculated. CONCLUSIONS: MAPSE measurement by an untrained observer was found to be a highly accurate predictor of EF.

Atrial fibrillation is a common, clinically significant arrhythmic disorder that results in increased risk of morbidity and mortality in affected patients. Atrial fibrillation is more prevalent among men compared with women and the risk for developing atrial fibrillation increases with advancing age. Ischaemic stroke is the most common clinical manifestation of embolic events from atrial fibrillation. While anticoagulation treatment is the preferred treatment, unfortunately, many patients have contraindications for anticoagulation treatment making this option unavailable to them. Previous data have shown that most thrombi that form in association with non-valvular atrial fibrillation occur in the left atrial appendage (LAA). It has been suggested that isolating the LAA from the body of the left atrium might reduce the risk of embolic events and that LAA obliteration may be a treatment option for patients with atrial fibrillation who are not candidates for anticoagulation treatment. Several procedures have been developed for isolation of the LAA, including surgical procedures as well as catheter-based ones. In this paper, we will review the currently available techniques, emphasizing the catheter-based ones. We will examine the increasing role of real-time three-dimensional transoesophageal echocardiography for appropriate screening and patient selection for these procedures, intra-procedural guidance, and follow-up care.

BACKGROUND: Catheter-based mitral valve clip repair (CBMCR) is feasible for selected patients with mitral regurgitation (MR). Two-dimensional (2D) transesophageal echocardiography (TEE) is the standard modality for evaluating MR and procedural guidance. Recently, real-time three-dimensional TEE became available. The aim of this study was to evaluate the value of combined 2D and three-dimensional TEE for CBMCR. In evaluating MR for CBMCR, the confidence of interpretation of 2D TEE was compared with that of combined imaging for the localization of major valve pathology. In patients who underwent CBMCR, the outcomes and the duration of CBMCR were compared. METHODS: In this retrospective study, MR evaluation was performed by 2D TEE alone and by combined imaging in 80 and 57 patients, respectively. CBMCR was guided by 2D TEE alone in 20 patients and by combined imaging in 39 patients. RESULTS: Examination by combined imaging allowed en face visualization of mitral valve anatomy and MR jet origin. The confidence of interpretation by combined imaging was higher than for 2D TEE (1.1 +/- 0.3 vs 1.8 +/- 0.7, P < .001).The guidance of CBMCR by combined imaging facilitated alignment of the catheter trajectory, clip positioning, and orientation of clip arms. The procedural success and final MR grade were not different between the two study groups. However, the procedural time of CBMCR using combined imaging compared with that using 2D TEE guidance alone was shorter (241 +/- 58 vs 201 +/- 68 min, P = .035). CONCLUSIONS: The use of combined imaging compared with 2D TEE alone appears to enhance the confidence of interpretation concerning mitral pathology and catheter-clip system location and may also reduce CBMCR time

BACKGROUND: There are currently no standardized three-dimensional (3D) transesophageal echocardiographic (TEE) views of the interatrial septum and atrial septal defects (ASDs). Without a standardized approach, it is difficult to ascertain the important anatomic relationships (such as the location of the aortic rim of an ASD), to perform relevant measurements (such as the size of an ASD or the size of its rims), or to guide the deployment of catheters and devices during atrial septal closure. METHODS: Using a 3D TEE matrix-array transducer, 706 TEE studies were performed over a 14-month period. The purpose of the study was to develop a standardized protocol for anatomically correct orientation of 3D TEE images of the interatrial septum and ASDs. RESULTS: Among 706 TEE studies, there were 23 patients with ASDs, representing 3.3% of the study population. Eighteen patients had secundum ASDs, two had primum ASDs, and three had sinus venosus ASDs of the superior vena cava type. A protocol for properly orienting 3D TEE images of the interatrial septum and ASDs was developed. When the images are acquired at an angle of 0 degrees , the septum is properly oriented by the tilt-up-then-left maneuver. The initial 3D TEE image in first tilted up to reveal the right atrial side of the septum. Then the image is tilted 180 degrees around its vertical axis to reveal the left atrial side of the septum; the aortic rim is on the left, the superior vena cava on the top, and the right-sided pulmonary vein ostia on the right side of the screen. For acquisitions at a higher angle, the rotate-left-in-z-axis maneuver is used. The image is first tilted up to reveal the right atrial side of the septum, as in the tilt-up-then-left maneuver. The image is then rotated counterclockwise in the z axis until the superior vena cave is at 12 o'clock. Finally, the image is tilted 180 degrees around its vertical axis to reveal the left atrial side of the septum. CONCLUSIONS: The use of standardized tilt-up-then-left and rotate-left-in-z-axis maneuvers enhances the diagnosis of ASDs, ascertains the important anatomic relationships of ASDs to surrounding structures, and facilitates communication between echocardiographers obtaining 3D TEE images and interventional cardiologists or cardiac surgeons performing ASD closures