Beta-blockers in pulmonary arterial hypertension: Time for a second thought?

Pulmonary arterial hypertension (PAH) is a heart failure syndrome characterized by right ventricular (RV) to pulmonary circulation uncoupling, counteracted by the sympathetic nervous system activation leading to ß1-receptors and α-myosin heavy chain downregulation, downregulation of the sarcoplasmic reticulum Ca2+ATPase, and ß-myosin heavy chain upregulation. Increased ventilation (VE) associated with VE inefficiency further characterizes PAH, as shown by an elevated VE versus carbon dioxide relationship slope during exercise, reflecting a specific behavior with progressive increase of dead space (VD) VE. The sympathetic system interacts with chemoreceptor-mediated VE control with increased VD leading to VE/perfusion mismatch. Growing evidence in the experimental models shows beneficial effects of different adrenoreceptor blockers on both right heart and pulmonary artery morphology and function. These effects can significantly change among ß-blockers according to their different pharmacokinetic and pharmacodynamic profiles. Since the first observation in the clinical setting, showing improvement associated with ß-blocker withdraw in PAH patients, recent studies suggest that the effects of ß-blockers in PAH might be related to the ß1-adrenergic receptors selectivity and α1- and ß3-related ancillary properties. While in the advanced stages of PAH ß-blockers may result deleterious as counteract the compensatory adrenergic-mediated effects of low cardiac output, in the early stages the modulation of the adrenergic system could ultimately improve VE efficiency and promote beneficial effects on heart failure gene expression and RV remodeling, particularly ß1-selective blockers and those associated with α- or ß3-activities. At present, all the above are physiologically sound but clinically unproven suggestions, and need to be tested in future randomized controlled trials.

Multiple hormonal and metabolic deficiency syndrome in chronic heart failure: rationale, design, and demographic characteristics of the T.O.S.CA. Registry.

Recent evidence supports the concept that progression of chronic heart failure (CHF) depends upon an imbalance of catabolic forces over the anabolic drive. In this regard, multiple hormonal deficiency syndrome (MHDS) significantly has impacts upon CHF progression, and is associated with a worse clinical status and increased mortality. The T.O.S.CA. (Trattamento Ormonale nello Scompenso CArdiaco; Hormone Therapy in Heart Failure) Registry (clinicaltrial.gov = NCT02335801) tests the hypothesis that anabolic deficiencies reduce survival in a large population of mild-to-moderate CHF patients. The T.O.S.CA. Registry is a prospective multicenter observational study coordinated by "Federico II" University of Naples, and involves 19 centers situated throughout Italy. Thyroid hormones, insulin-like growth factor-1, total testosterone, dehydroepiandrosterone , and insulin are measured at baseline and every year for a patient-average follow-up of 3 years. Subjects with CHF are divided into two groups: patients with one or no anabolic deficiency, and patients with two or more anabolic deficiencies at baseline. The primary endpoint is the composite of all-cause mortality and cardiovascular hospitalization. Secondary endpoints include the composite of all-cause mortality and hospitalization, the composite of cardiovascular mortality and cardiovascular hospitalization, and change of VO2 peak. Patient enrollment started in April 2013, and was completed in July 2017. Demographics and main clinical characteristics of enrolled patients are provided in this article. Detailed cross-sectional results will be available in late 2018. The T.O.S.CA. Registry represents the most robust prospective observational trial on MHDS in the field of CHF. The study findings will advance our knowledge with regard to the intimate mechanisms of CHF progression and hopefully pave the way for future randomized clinical trials of single or multiple hormonal replacement therapies in CHF.

Heart failure: molecular, genetic and epigenetic features of the disease.

Factors that compete to establish heart failure (HF) are not completely known. In the last years the several technological improvements allowed us to deeply study the molecular and genetic aspects of this complex syndrome. This new approach to HF based on molecular biology new discoveries shows us more clearly the pathophysiological bases of this disease, and a future scenery where the genetics may be useful in the clinical practice, as screening of high risk populations, as well as in the diagnosis and therapy of underlying myocardial diseases. The purpose of this review was to analyse the molecular, genetic and epigenetic factors of HF. We described the molecular anatomy of the sarcomere and the pathogenesis of the heart muscle diseases, abandoning the previous monogenic theory for the concept of a polygenic disease. Different actors play a role to cause the illness by themselves, modifying the expression of the disease and, eventually, the prognosis of the patient.

Novel insights into the role of cardiotrophin-1 in cardiovascular diseases.

Cardiotrophin-1 (CT-1), a member of interleukin (IL)-6 family, was originally isolated for its ability to induce a hypertrophic response in neonatal cardiac myocytes. This cytokine mediates a pleiotropic set of growth and differentiation activities through a unique receptor system, consisting of IL-6 receptor (IL-6R) and a common signal transducer, the glycoprotein 130 (gp130). Both in humans and in mice, CT-1 mRNA has been detected in several tissues, such as liver tissue, adipose tissue, and tissues in the respiratory and nervous systems; in each of these tissues it performs different functions. Predominant actions of CT-1 are on the heart, where it is synthesized and where it provides first myocardial protection by promoting cell survival and proliferation, it carries on its haemodynamic effects and endocrine properties, and finally, it predisposes the heart to pathological conditions. The aim of this review is to describe the pathophysiological mechanisms through which CT-1 carries out its activities, especially on the heart, and its potential contribution as a disease marker in clinical cardiology. Recent studies have confirmed its active role in promoting structural changes typical of most common cardiovascular disease, such as hypertension, valve diseases, congestive heart failure, and coronary artery disease. In fact, CT-1 induces myocyte hypertrophy and collagen synthesis, thereby participating in the progression of ventricular remodelling, which results in cardiac muscle failure at the latest stage. CT-1 plasma levels are elevated in patients with hypertension and coronary artery diseases, and they are also correlated with the severity of valve diseases and heart failure. Therefore, CT-1 may represent a diagnostic, staging, and prognostic biomarker of cardiovascular diseases.

[The role of natriuretic peptides in heart failure]. / Ruolo dei peptidi natriuretici nello scompenso cardiaco.

Over the last decades, there has been a significant increase in incidence and prevalence of heart failure, a major cause of cardiac morbidity and mortality. Measurements of neurohormones, in particular B-type natriuretic peptide (BNP), can significantly improve diagnostic accuracy, and also correlate with long-term morbidity and mortality in patients with chronic heart failure presenting to the emergency department. BNP is secreted by cardiac ventricles mainly in response to wall stress and neurohormonal factors like the sympathetic nervous system, endothelins, and the rennin-angiotensin-aldosterone system. BNP increases myocardial relaxation and oppose the vasoconstrictive, sodium retaining, and natriuretic effects caused by vasoconstrictive factors. BNP is the first biomarker to prove its clinical value for the diagnosis of left ventricular systolic and diastolic dysfunction but also for the right ventricular dysfunction, guiding prognosis and therapy management. Emerging clinical data will help further refine biomarker-guided therapeutic and monitoring strategies involving BNP.