Right ventricular strain in heart failure: Clinical perspective.

The number of studies demonstrating the importance of right ventricular remodelling in a wide range of cardiovascular diseases has increased in the past two decades. Speckle-tracking imaging provides new variables that give comprehensive information about right ventricular function and mechanics. In this review, we summarize current knowledge of right ventricular mechanics in heart failure with reduced ejection fraction and preserved ejection fraction. We searched PubMed, MEDLINE, Ovid and Embase databases for studies published from January 2000 to December 2016 in the English language using the following keywords: "right ventricle"; "strain"; "speckle tracking"; "heart failure with reduced ejection fraction"; and "heart failure with preserved ejection fraction". Investigations showed that right ventricular dysfunction is associated with higher cardiovascular and overall mortality in patients with heart failure, irrespective of ejection fraction. The number of studies investigating right ventricular strain in patients with heart failure with reduced ejection fraction is constantly increasing, whereas data on right ventricular mechanics in patients with heart failure with preserved ejection fraction are limited. Given the high feasibility, accuracy and clinical implications of right ventricular strain in the population with heart failure, it is of great importance to try to include the evaluation of right ventricular strain as a regular part of each echocardiographic examination in patients with heart failure. However, further investigations are necessary to establish right ventricular strain as a standard variable for decision-making.

Left ventricular strain and twisting in heart failure with preserved ejection fraction: an updated review.

Despite the high prevalence of the patients with heart failure with preserved ejection fraction (HFpEF), our knowledge about this entity, from diagnostic tools to therapeutic approach, is still not well established. The evaluation of patients with HFpEF is mainly based on echocardiography, as the most widely accepted tool in cardiac imaging. Identification of left ventricular (LV) diastolic dysfunction has long been considered as the only responsible for HFpEF, and its evaluation is still "sine qua non" of HFpEF diagnostics. However, one should be aware of the fact that identifying cardiac dysfunction in HFpEF might be very challenging and often needs more complex evaluation of cardiac structure and function. New echocardiographic modalities such as 2D and 3D speckle tracking imaging could help in the diagnosis of HFpEF and provide further information regarding LV function and mechanics. Early diagnosis, medical management, and adequate monitoring of HFpEF patients are prerequisites of modern medical treatment. New healthcare approaches require individualized patient care, which is why clinicians should have all clinical, laboratory, and diagnostic data before making final decisions about the treatment of any patients. This is particularly important for HFpEF that often remains undiagnosed for quite a long time, which further prolongs the beginning of adequate treatment and brings into question outcome of these patients. The aim of this article is to provide the overview of the main principles of LV mechanics and summarize recent data regarding LV strain in patients with HFpEF.

Stretch-elicited Na+/H+ exchanger activation: the autocrine/paracrine loop and its mechanical counterpart.

The stretch of the cardiac muscle is immediately followed by an increase in the contraction strength after which occurs a slow force increase (SFR) that takes several minutes to fully develop. The SFR was detected in a wide variety of experimental preparations including isolated myocytes, papillary muscles and/or trabeculae, left ventricle strips of failing human myocardium, in vitro isovolumic and in vivo volume-loaded hearts. It was established that the initial increase in force is due to an increase in myofilament Ca2+ responsiveness, whereas the SFR results from an increase in the Ca2+ transient. However, the mechanism(s) for this increase in the Ca2+ transient has remained undefined until the proposal of Na+/H+ exchanger (NHE) activation by stretch. Studies in multicellular cardiac muscle preparations from cat, rabbit, rat and failing human heart have shown evidence that the stretch induces a rise in intracellular Na+ ([Na+]i) through NHE activation, which subsequently leads to an increase in Ca2+ transient via reverse-mode Na+/Ca2+ (NCX) exchange. These experimental data agree with a theoretical ionic model of cardiomyocytes that predicted an increased Na+ influx and a concurrent increase in Ca2+ entry through NCX as the cause of the SFR to muscle stretch. However, there are aspects that await definitive demonstration, and perhaps subjected to species-related differences like the possibility of an autocrine/paracrine loop involving angiotensin II and endothelin as the underlying mechanism for stretch-induced NHE activation leading to the rise in [Na+]i and reverse-mode NCX.