Etiology of Anemia in Patients With Advanced Heart Failure

ObjectivesWe prospectively investigated the causes of anemia in patients with advanced congestive heart failure (CHF).BackgroundAnemia is common in patients with advanced CHF, and its etiology is generally considered to be multifactorial. However, despite its importance, precise information is lacking regarding the prevalence of putative etiologic factors.MethodsPatients who were hospitalized for decompensated advanced CHF and who were stabilized after their initial treatment underwent evaluation of “clinically significant” anemia, defined as a hemoglobin content <12 g/dl for men and <11.5 g/dl for women. Patients with a serum creatinine concentration >3 mg/dl or patients with concurrent diseases that are known to cause anemia were not included. The initial evaluation included measurements of vitamin B12, folic acid, thyroid-stimulating hormone, erythropoietin, lactate dehydrogenase, Coombs test, multiple fecal occult tests, and bone marrow aspiration. Patients without diagnosis by these methods underwent red cell mass measurement with 51Cr assay.ResultsThe mean age of the 37 patients was 57.9 ± 10.9 years and mean left ventricular ejection fraction 22.5 ± 5.9%. Iron deficiency anemia was confirmed by bone marrow aspiration in 27 patients (73%), 2 patients (5.4%) had dilutional anemia, and 1 patient (2.7%) had drug-induced anemia. No specific cause was identified in 7 patients (18.9%) who were considered to have “anemia of chronic disease.” Serum ferritin for the iron-deficient patients was not a reliable marker of iron deficiency in this population.ConclusionsIn this group of patients, iron deficiency was the most common cause of anemia. The iron status of patients with end-stage chronic CHF should be thoroughly evaluated and corrected before considering other therapeutic interventions

Impact of Mechanical Unloading on Microvasculature and Associated Central Remodeling Features of the Failing Human Heart

ObjectivesThis study investigates alterations in myocardial microvasculature, fibrosis, and hypertrophy before and after mechanical unloading of the failing human heart.BackgroundRecent studies demonstrated the pathophysiologic importance and significant mechanistic links among microvasculature, fibrosis, and hypertrophy during the cardiac remodeling process. The effect of left ventricular assist device (LVAD) unloading on cardiac endothelium and microvasculature is unknown, and its influence on fibrosis and hypertrophy regression to the point of atrophy is controversial.MethodsHemodynamic data and left ventricular tissue were collected from patients with chronic heart failure at LVAD implant and explant (n = 15) and from normal donors (n = 8). New advances in digital microscopy provided a unique opportunity for comprehensive whole-field, endocardium-to-epicardium evaluation for microvascular density, fibrosis, cardiomyocyte size, and glycogen content. Ultrastructural assessment was done with electron microscopy.ResultsHemodynamic data revealed significant pressure unloading with LVAD. This was accompanied by a 33% increase in microvascular density (p = 0.001) and a 36% decrease in microvascular lumen area (p = 0.028). We also identified, in agreement with these findings, ultrastructural and immunohistochemical evidence of endothelial cell activation. In addition, LVAD unloading significantly increased interstitial and total collagen content without any associated structural, ultrastructural, or metabolic cardiomyocyte changes suggestive of hypertrophy regression to the point of atrophy and degeneration.ConclusionsThe LVAD unloading resulted in increased microvascular density accompanied by increased fibrosis and no evidence of cardiomyocyte atrophy. These new insights into the effects of LVAD unloading on microvasculature and associated key remodeling features might guide future studies of unloading-induced reverse remodeling of the failing human heart

Evidence of Glycolysis Up-Regulation and Pyruvate Mitochondrial Oxidation Mismatch During Mechanical Unloading of the Failing Human Heart: Implications for Cardiac Reloading and Conditioning

This study sought to investigate the effects of mechanical unloading on myocardial energetics and the metabolic perturbation of heart failure (HF) in an effort to identify potential new therapeutic targets that could enhance the unloading-induced cardiac recovery. The authors prospectively examined paired human myocardial tissue procured from 31 advanced HF patients at left ventricular assist device (LVAD) implant and at heart transplant plus tissue from 11 normal donors. They identified increased post-LVAD glycolytic metabolites without a coordinate increase in early, tricarboxylic acid (TCA) cycle intermediates. The increased pyruvate was not directed toward the mitochondria and the TCA cycle for complete oxidation, but instead, was mainly converted to cytosolic lactate. Increased nucleotide concentrations were present, potentially indicating increased flux through the pentose phosphate pathway. Evaluation of mitochondrial function and structure revealed a lack of post-LVAD improvement in mitochondrial oxidative functional capacity, mitochondrial volume density, and deoxyribonucleic acid content. Finally, post-LVAD unloading, amino acid levels were found to be increased and could represent a compensatory mechanism and an alternative energy source that could fuel the TCA cycle by anaplerosis. In summary, the authors report evidence that LVAD unloading induces glycolysis in concert with pyruvate mitochondrial oxidation mismatch, most likely as a result of persistent mitochondrial dysfunction. These findings suggest that interventions known to improve mitochondrial biogenesis, structure, and function, such as controlled cardiac reloading and conditioning, warrant further investigation to enhance unloading-induced reverse remodeling and cardiac recovery

Cardiac Allograft Vasculopathy in Redo-transplants: Is it More or Less the Same the Second Time Around?

Purpose: Cardiac allograft vasculopathy (CAV) continues to hinder the long-term success of heart transplant recipients.  Redo-transplantation is currently the only definitive treatment for advanced CAV. We examined whether these patients are at similar CAV-risk with the second transplantMethods: Heart recipients from 1985 to 2011 at the UTAH program were included in the study and those with CAV as an indication for redo-transplantation were identified. CAV diagnosis was made by coronary angiography and based on the 2010 ISHLT standardized nomenclature for CAV. Patient demographics, rejection history, and CAV incidence were analyzed. Results: Of the 1,169 eligible patients, 135 (11.5%) developed CAV post their first transplant; 78 cases within 10 years and 54 beyond 10 years. The mean time to CAV was 6.58 years. Of the 135 patients who developed CAV, only 21 (15.5%) ended up requiring a redo-transplant. Of the 21 retransplanted patients, 4 (19.0%) developed CAV again; 2 patients within 10 years and 2 patients beyond 10 years indicating a similar risk for CAV occurrence for first and redo-transplant. Conclusions: Our results indicate that CAV is as likely to develop in redo-transplants despite recent advances in immunosuppression and the standardized use of lipid-lowering agents. Although outcomes in redo-transplantation for the indication of CAV are favorable, efforts to better understand and minimize CAV are needed, especially in the face of scarce donor organs

Epigenetic response to environmental stress: Assembly of BRG1–G9a/GLP–DNMT3 repressive chromatin complex on Myh6 promoter in pathologically stressed hearts

Chromatin structure is determined by nucleosome positioning, histone modifications, and DNA methylation. How chromatin modifications are coordinately altered under pathological conditions remains elusive. Here we describe a stress-activated mechanism of concerted chromatin modification in the heart. In mice, pathological stress activates cardiomyocytes to express Brg1 (nucleosome-remodeling factor), G9a/Glp (histone methyltransferase), and Dnmt3 (DNA methyltransferase). Once activated, Brg1 recruits G9a and then Dnmt3 to sequentially assemble repressive chromatin—marked by H3K9 and CpG methylation—on a key molecular motor gene (Myh6), thereby silencing Myh6 and impairing cardiac contraction. Disruption of Brg1, G9a or Dnmt3 erases repressive chromatin marks and de-represses Myh6, reducing stress-induced cardiac dysfunction. In human hypertrophic hearts, BRG1–G9a/GLP–DNMT3 complex is also activated; its level correlates with H3K9/CpG methylation, Myh6 repression, and cardiomyopathy. Our studies demonstrate a new mechanism of chromatin assembly in stressed hearts and novel therapeutic targets for restoring Myh6 and ventricular function. The stress-induced Brg1–G9a–Dnmt3 interactions and sequence of repressive chromatin assembly on Myh6 illustrates a molecular mechanism by which the heart epigenetically responds to environmental signals. This article is part of a Special Issue entitled: Cardiomyocyte Biology: Integration of Developmental and Environmental Cues in the Heart edited by Marcus Schaub and Hughes Abriel

The evolving field of nonpharmacological therapies to improve functional capacity in chronic heart failure

Clinical investigations in chronic heart failure (HF) have been increasingly including endpoints related to functional and exercise capacity. Noninvasive ventilation support (NIVS) constitutes a therapeutic option that could improve several markers of cardiovascular performance and functional capacity along with improvements in HF symptoms such as dyspnea. NIVS with bilevel positive airway pressure (BiPAP) is a therapeutic option that can be better tolerated by patients than continuous positive airway pressure (cPAP) and potentially improve the adherence of patients with HF to NIVS. Future investigations should improve our understanding as to how to select patients with HF most amenable to respond favorably, elucidate the frequency and duration of NIVS session required to maintain the observed short-term beneficial effects for a long period of time, and shed additional light on the mechanisms associated with these benefits. In summary, NIVS appears to be a promising nonpharmacological therapy to improve exercise capacity and quality of life in chronic HF. (C) 2018 Hellenic Society of Cardiology. Publishing services by Elsevier B.V

The evolving field of nonpharmacological therapies to improve functional capacity in chronic heart failure

Clinical investigations in chronic heart failure (HF) have been increasingly including endpoints related to functional and exercise capacity. Noninvasive ventilation support (NIVS) constitutes a therapeutic option that could improve several markers of cardiovascular performance and functional capacity along with improvements in HF symptoms such as dyspnea. NIVS with bilevel positive airway pressure (BiPAP) is a therapeutic option that can be better tolerated by patients than continuous positive airway pressure (cPAP) and potentially improve the adherence of patients with HF to NIVS. Future investigations should improve our understanding as to how to select patients with HF most amenable to respond favorably, elucidate the frequency and duration of NIVS session required to maintain the observed short-term beneficial effects for a long period of time, and shed additional light on the mechanisms associated with these benefits. In summary, NIVS appears to be a promising nonpharmacological therapy to improve exercise capacity and quality of life in chronic HF