Comparison of Radifocus versus Silverway Guidewires for Percutaneous Radial Angiography Following Failed Use of a J-Tip Guidewire.

BACKGROUND During transradial coronary angiography, when conventional J-tip wires fail to deliver catheters to the aortic root due to anatomical obstacles, additional hydrophilic wires, such as Radifocus (Terumo) or Silverway (Asahi), are used. We recently showed that the Silverway guidewire was effective at delivering the catheter to the aortic root. In this study, we aimed to compare the efficacy and safety of Radifocus and Silverway guidewires in 100 patients after failed use of the J-tip guidewire. MATERIAL AND METHODS After patients had a failure of a conventional J-tip wire to reach the aortic root, 100 patients were 1:1 randomized to either the Silverway or Radifocus wire. All patients with failure of the J-tip wire were eligible. The primary endpoint was the time between wire entry in the catheter and successful delivery of the catheter to the aortic root. Secondary endpoints included change of access site, number of complications, and questionnaires on subjective wire assessments by the performing interventional cardiologist. RESULTS The primary endpoint was significantly shorter in patients randomized to the Silverway arm (median 30 s [21-39] vs 48 s [36-66]; P<0.001)). The percentage of patients with change of access site was not different between the groups (2 vs 2, not significant). Only 1 minor complication (2%) occurred, in the Radifocus group. Questionnaires revealed that torque control, crossing, and support were all significantly better with the Silverway wire (P<0.001). CONCLUSIONS Silverway showed superior torque control, resulting in faster catheter delivery to the aortic root when compared with the Radifocus guidewire.

MicroRNA-216a is essential for cardiac angiogenesis.

While it is experimentally supported that impaired myocardial vascularization contributes to a mismatch between myocardial oxygen demand and supply, a mechanistic basis for disruption of coordinated tissue growth and angiogenesis in heart failure remains poorly understood. Silencing strategies that impair microRNA biogenesis have firmly implicated microRNAs in the regulation of angiogenesis, and individual microRNAs prove to be crucial in developmental or tumor angiogenesis. A high-throughput functional screening for the analysis of a whole-genome microRNA silencing library with regard to their phenotypic effect on endothelial cell proliferation as a key parameter, revealed several anti- and pro-proliferative microRNAs. Among those was miR-216a, a pro-angiogenic microRNA which is enriched in cardiac microvascular endothelial cells and reduced in expression under cardiac stress conditions. miR-216a null mice display dramatic cardiac phenotypes related to impaired myocardial vascularization and unbalanced autophagy and inflammation, supporting a model where microRNA regulation of microvascularization impacts the cardiac response to stress.

The adult heart requires baseline expression of the transcription factor Hand2 to withstand right ventricular pressure overload.

AIMS: Research on the pathophysiology of right ventricular (RV) failure has, in spite of the associated high mortality and morbidity, lagged behind compared to the left ventricle (LV). Previous work from our lab revealed that the embryonic basic helix-loop-helix transcription factor heart and neural crest derivatives expressed-2 (Hand2) is re-expressed in the adult heart and activates a 'foetal gene programme' contributing to pathological cardiac remodelling under conditions of LV pressure overload. As such, ablation of cardiac expression of Hand2 conferred protection to cardiac stress and abrogated the maladaptive effects that were observed upon increased expression levels. In this study, we aimed to understand the contribution of Hand2 to RV remodelling in response to pressure overload induced by pulmonary artery banding (PAB). METHODS AND RESULTS: In this study, Hand2F/F and MCM- Hand2F/F mice were treated with tamoxifen (control and knockout, respectively) and subjected to six weeks of RV pressure overload induced by PAB. Echocardiographic- and MRI-derived haemodynamic parameters as well as molecular remodelling were assessed for all experimental groups and compared to sham-operated controls. Six weeks after PAB, levels of Hand2 expression increased in the control-banded animals but, as expected, remained absent in the knockout hearts. Despite the dramatic differences in Hand2 expression, pressure overload resulted in impaired cardiac function independently of the genotype. In fact, Hand2 depletion seems to sensitize the RV to pressure overload as these mice develop more hypertrophy and more severe cardiac dysfunction. Higher expression levels of HAND2 were also observed in RV samples of human hearts from patients with pulmonary hypertension. In turn, the LV of RV pressure-overloaded hearts was also dramatically affected as reflected by changes in shape, decreased LV mass, and impaired cardiac function. RNA-sequencing revealed a distinct set of genes that are dysregulated in the pressure-overloaded RV, compared to the previously described pressure-overloaded LV. CONCLUSION: Cardiac-specific depletion of Hand2 is associated with severe cardiac dysfunction in conditions of RV pressure overload. While inhibiting Hand2 expression can prevent cardiac dysfunction in conditions of LV pressure overload, the same does not hold true for conditions of RV pressu re overload. This study highlights the need to better understand the molecular mechanisms driving pathological remodelling of the RV in contrast to the LV, in order to better diagnose and treat patients with RV or LV failure.

miR-199b-5p is a regulator of left ventricular remodeling following myocardial infarction.

Myocardial infarction (MI), the globally leading cause of heart failure, morbidity and mortality, involves post-MI ventricular remodeling, a complex process including acute injury healing, scar formation and global changes in the surviving myocardium. The molecular mechanisms involved in adverse post-infarct left ventricular remodeling still remain poorly defined. Recently, microRNAs have been implicated in the development and progression of various cardiac diseases as crucial regulators of gene expression. We previously demonstrated that in a murine model of pressure overload, a model of heart failure secondary to aortic stenosis or chronic high blood pressure, elevated myocardial expression of miR-199b-5p is sufficient to activate calcineurin/NFAT signaling, leading to exaggerated cardiac pathological remodeling and dysfunction. Given the differences in left ventricular remodeling secondary to post-infarct healing and pressure overload, we evaluated miR-199b function in post-MI remodeling. We confirmed that the expression of miR-199b is elevated in the post-infarcted heart. Transgenic animals with cardiomyocyte-restricted overexpression of miR-199b-5p displayed exaggerated pathological remodeling after MI, reflected by severe systolic and diastolic dysfunction and fibrosis deposition. Conversely, therapeutic silencing of miR-199b-5p in MI-induced cardiac remodeling by using an antagomir to specifically inhibit endogenous miR-199b-5p in vivo, resulted in efficient suppression of cardiac miR-199b-5p expression and attenuated cardiac dysfunction and dilation following MI. Mechanistically, miR-199b-5p influenced the expression of three predicted target genes in post-infarcted hearts, dual specificity tyrosine-phosphorylation-regulated kinase 1A (Dyrk1a), the notch1 receptor and its ligand jagged1. In conclusion, here we provide evidence supporting that stress-induced miR-199b-5p participates in post-infarct remodeling by simultaneous regulation of distinct target genes.

Adaptive capacity of the right ventricle: why does it fail?

Only in recent years has the right ventricle (RV) function become appreciated to be equally important to the left ventricle (LV) function to maintain cardiac output. Right ventricular failure is, irrespectively of the etiology, associated with impaired exercise tolerance and poor survival. Since the anatomy and physiology of the RV is distinctly different than that of the LV, its adaptive mechanisms and the pathways involved are different as well. RV hypertrophy is an important mechanism of the RV to preserve cardiac output. This review summarizes the current knowledge on the right ventricle and its response to pathologic situations. We will focus on the adaptive capacity of the right ventricle and the molecular pathways involved, and we will discuss potential therapeutic interventions.

Supplementing exposure to hypoxia with a copper depleted diet does not exacerbate right ventricular remodeling in mice.

BACKGROUND: Pulmonary hypertension and subsequent right ventricular (RV) failure are associated with high morbidity and mortality. Prognosis is determined by occurrence of RV failure. Currently, adequate treatment for RV failure is lacking. Further research into the molecular basis for the development of RV failure as well as the development of better murine models of RV failure are therefore imperative. We hypothesize that adding a low-copper diet to chronic hypoxia in mice reinforces their individual effect and that the combination of mild pulmonary vascular remodeling and capillary rarefaction, induces RV failure. METHODS: Six week old mice were subjected to normoxia (N; 21% O2) or hypoxia (H; 10% O2) during a period of 8 weeks and received either a normal diet (Cu+) or a copper depleted diet (Cu-). Cardiac function was assessed by echocardiography and MRI analysis. RESULTS AND CONCLUSION: Here, we characterized a mouse model of chronic hypoxia combined with a copper depleted diet and demonstrate that eight weeks of chronic hypoxia (10%) is sufficient to induce RV hypertrophy and subsequent RV failure. Addition of a low copper diet to hypoxia did not have any further deleterious effects on right ventricular remodeling.

Genetics and epigenetics of arrhythmia and heart failure.

Heart failure (HF) is the end stage of several pathological cardiac conditions including myocardial infarction, cardiac hypertrophy and hypertension. Various molecular and cellular mechanisms are involved in the development of HF. At the molecular level, the onset of HF is associated with reprogramming of gene expression, including downregulation of the alpha-myosin heavy chain (α-MHC) gene and sarcoplasmic reticulum Ca (2+) ATPase genes and reactivation of specific fetal cardiac genes such as atrial natriuretic factor and brain natriuretic peptide. These deviations in gene expression result in structural and electrophysiological changes, which eventually progress to HF. Cardiac arrhythmia is caused by altered conduction properties of the heart, which may arise in response to ischemia, inflammation, fibrosis, aging or from genetic factors. Because changes in the gene transcription program may have crucial consequences as deteriorated cardiac function, understanding the molecular mechanisms involved in the process has become a priority in the field. In this context, various studies besides having identified different DNA methylation patterns in HF patients, have also focused on specific disease processes and their underlying mechanisms, also introducing new concepts such as epigenomics. This review highlights specific genetic mutations associated with the onset and progression of HF, also providing an introduction to epigenetic mechanisms such as histone modifications, DNA methylation and RNA-based modification, and highlights the relation between epigenetics, arrhythmogenesis and HF.