Right atrial function is associated with RV diastolic stiffness: RA-RV interaction in pulmonary arterial hypertension

BackgroundPulmonary arterial hypertension (PAH) patients have altered right atrial (RA) function and right ventricular (RV) diastolic stiffness. This study assessed the impact of RV diastolic stiffness on RA-RV interaction.MethodsLow or high end-diastolic elastance (Eed) PAH patients (n=94) were compared to controls (n=31). Treatment response was evaluated in n=62 patients. RV and RA longitudinal strain, RA emptying and RV filling were determined and diastole was divided in a passive and active phase. Vena cava backflow was calculated as RV active filling-RA active emptying; RA stroke work as RA active emptying*RV end-diastolic pressure.ResultsWith increased Eed, RA and RV passive strain were reduced while active strain was preserved. In comparison to controls, patients had lower RV passive filling, but higher RA active emptying and RA stroke work. RV active filling was lower in high Eed patients, resulting in higher vena cava backflow. Upon treatment, Eed reduced in half of high Eedpatients, which coincided with larger reductions in afterload, RV mass and vena cava backflow and greater improvements in RV active filling and stroke volume in comparison to patients in whom Eed remained high.ConclusionsIn PAH, RA function is associated with changes in RV function. Despite increased RA stroke work, severe RV diastolic stiffness is associated with reduced RV active filling and increased vena cava backflow. In 50% of high baseline Eed patients, diastolic stiffness remains high, despite treatment. Eed reduction coincided with a large reduction in afterload, increased RV active filling and decreased vena cava backflow.

Diastolic disorder inherent to doxorubicin cardiotoxicity

Background: The doxorubicin (Dx) cardiotoxicity is manifested by a marked heart failure evolution. The impact of Dx on lusitrop functions of the heart and the inherent diastolic disorders have a theoretical and practical value for the connection cardiology-oncology. Material and methods: Dx cardiotoxicity was reproduced by its administration i/p in white rats in cumulative dose 16 mg/kg (Dx group n=9). Control group (n=9) received only physiological solution. The study was performed in vitro by using models of isolated heart perfusion in either isovolumic or exterior working regimens. The assayed indices of diastole functioning were: left ventricle (LV) end-diastolic pressure (LVEDP), diastolic stiffness, isovolumic relaxation velocity (-dP/dTmax) and protodiastolic pressure of LV (LVPDP). Results: The indices of diastolic disorders induced by Dx were elevation of LVEDP, diastolic stiffness and LVPDP in a range of 97-168% comparing to control as well as diminution of -dP/dTmax in the physiological pattern of hemodynamics. LVEDP increased more in conditions of calcium overloading or endothelin-1 (ET-1) action that are involved in pathogenesis of diastolic rigidity. Dx action led to decrease of myocardium resistance to ischemiareperfusion action resulting in the LVEDP elevation by 53% comparing to control. Conclusions: 1. Diastolic disorders inherent to Dx cardiotoxicity are manifested by the increase of LVEDP and diastolic stiffness. 2. Diastolic disorders compromised the volume-pressure relationship of LV, the adaptation of the heart to effort with volume, being more pronounced during the action of calcium excess and ET-1

Abstract P104: Simultaneous Treatment With Ivabradine And Spironolactone Does Not Modify Hypertension-induced Myocardial Fibrosis In Dahl Salt-sensitive Rats

Background: Hypertension (HT)-induced accumulation of myocardial collagen stiffens the left ventricular (LV) wall and, hence, promotes diastolic dysfunction. Considering that a competitive aldosterone receptor antagonist spironolactone (SL) as well as a “pure” heart rate-lowering drug ivabradine (IVA) have both been proven to exert an anti-fibrotic effect during cardiac remodeling, we hypothesized that, in combination, these drugs would complement each other in alleviating HT-induced myocardial fibrosis and, therefore, could better preserve diastolic function. Methods: Sustained HT was induced in 7-week-old male Dahl salt-sensitive rats by feeding them a high-salt (8%) diet for 7 weeks. Then, HT rats were randomly assigned in two experimental groups: 1) IVA (10 mg/kg/day) + SL (20 mg/kg/day)-treated (HT-T) and 2) vehicle only (HT-V). The drugs and the vehicle (a mixture of 50% dimethyl sulfoxide/50% propylene glycol, v/v) were delivered IP by osmotic pumps for 8 weeks. The age-matched rats were used as normotensive controls (NT). Heart rate (HR) and blood pressure (BP) were recorded every other week using a CODA tail-cuff plethysmography system. At the end of the study, the hemodynamic parameters were assessed using a Millar pressure catheter and the hearts were collected for histology and quantitative morphometry. Statistical analysis was performed using Prism 6. Results: We found that during 8-week treatment period, BP had remained comparably elevated in both HT groups by ~26% (P≤0.01) on average vs. NT rats, whereas HR had been persistently reduced in HT-T group by ~38% and ~27% (P≤0.01) on average vs. HT-V and NT rats, respectively. At the end of the study period, all groups revealed a similar level of LV end-diastolic pressure, suggesting the analogous diastolic stiffness of the myocardium. At the same time, morphological examination of the hearts has confirmed that sustained HT caused significant interstitial and perivascular fibrosis (P≤0.01) in both experimental groups compared to NT rats, and that the treatment did not change the extent of fibrillar collagen accumulation as compared to HT-V rats. Conclusions: Taken together, our findings confirmed that a combined treatment with IVA and SL could not alleviate HT-induced myocardial fibrosis.

E-wave asymmetry elucidates diastolic ventricular stiffness-relaxation coupling: model-based prediction with in vivo validation

Although diastolic stiffness and relaxation are considered independent chamber properties, the cardio-hemic inertial oscillation that generates E-waves obeys Newton’s law. E-waves vary with heart rate requiring simultaneous change in stiffness and relaxation. By retrospective analysis of human heart-rate varying transmitral Doppler-data, we show that diastolic stiffness and relaxation are coupled and that the coupling manifests through E-wave asymmetry, quantified through a parametrized diastolic filling model-derived dimensionless parameter, which only depends on deceleration time and acceleration time, readily obtainable via standard echocardiography.

Abstract 14221: Right Ventricular Adaptation to Pressure Overload: Differences Between Chronic Thromboembolic Pulmonary Hypertension and Idiopathic Pulmonary Arterial Hypertension

Background: Chronic thromboembolic pulmonary hypertension (CTEPH) and idiopathic pulmonary arterial hypertension (iPAH)) are both associated with right ventricular (RV) failure and death. Although both conditions develop in the pre-capillary pulmonary vasculature, patient characteristics are different. CTEPH patients are older, predominantly male and more often have a history of venous thromboembolism. Therefore, the RV might be affected differently in CTEPH compared to iPAH. We aimed to compare RV adaptation in CTEPH and iPAH. Methods: Between 2000 and 2019 all treatment naive iPAH and CTEPH patients diagnosed in the Amsterdam UMC were included if a right heart catheterization and cardiac magnetic resonance imaging (CMR) were performed at the time of diagnosis. RV volumes, mass and function were assessed with CMR. RV contractility, afterload, RV-pulmonary artery (RV-PA) coupling and diastolic stiffness (Eed) were obtained using single beat pressure-volume loop analysis. Differences in RV phenotypes between iPAH and CTEPH were analyzed using multiple linear regression with interaction testing after correcting for confounders. Results: A total of 235 patients were included, 116 with CTEPH and 119 with iPAH. CTEPH patients were older, predominantly male, had a higher systemic blood pressure and a lower pulmonary vascular resistance at the time of diagnosis. After correcting for these confounders, RV function and RV-PA coupling were similar in both groups. However, CTEPH patients had a higher RV end-diastolic volume index (87±27 ml/m2 vs. 82±25 ml/m2), and a lower RV wall thickness (0,6±0,1 g/ml vs. 0,7±0,2 g/ml; figure 1A). The increase in afterload in CTEPH was associated with a disproportionally larger increase in diastolic stiffness compared to iPAH, independent of RV wall thickness (figure 1B). Conclusions: Despite a similar RV function, the RV in CTEPH is more dilated and stiffer than the RV in iPAH, independent of age, sex and afterload.

Acute effects of a mavacamten-like myosin-inhibitor (MYK-581 in a feline model of obstructed hypertrophic cardiomyopathy: evidence of improved ventricular filling (beyond obstruction reprieve)

Introduction Hypertrophic cardiomyopathy (HCM) is a progressive disease characterized by cardiac remodeling, hyperdynamic contraction, and impaired ventricular filling that can lead to dynamic left-ventricular outflow-track (LVOT) obstruction and exertional intolerance. Direct myosin-inhibition with mavacamten can normalize contractility and improve exercise capacity in patients with oHCM, providing sustained symptomatic relief. However, mavacamten can also improve ventricular filling by limiting residual cross-bridges during diastole, and therefore, may offer cardiac benefits beyond obstruction reprieve. This study leveraged a feline model of oHCM, cats with the A31P MYBPC3 variant, to study the acute in vivo effects of MYK-581, a mavacamten surrogate, on cardiac hemodynamics and filling. Methods A31P-homozygous cats with HCM (A31P, n=10) and wild-type healthy controls (CTRL, n=9) were anesthetized and instrumented for invasive pressure-volume (PV) measurements as well as trans-thoracic echocardiographic recording. A subset of cats were assigned to receive either vehicle (VEH, n=7) or MYK-581 (MYK, n=8) with a short IV infusion. Cardiac hemodynamics, function, and geometry were assessed at steady state before and during dobutamine challenges (2.5 μg/kg/min IV). Results A31P cats had thicker ventricular walls (6.4±0.1 vs. 5.2±0.2 mm, P<0.05) and hyperdynamic contraction (FS: 61±4 vs. 50±3%, P<0.05) relative to controls and presented with dynamic LVOT obstruction in 54% of cases. HCM cats had elevated end-diastolic pressures (17±1.4 vs. 9±1.0 mmHg, P<0.05), with prolonged time constants of relaxation (60±4.1 vs. 36±2.4 ms, P<0.05) and elevated end-diastolic stiffness (Eed: 0.44±0.06 vs. 0.25±0.01 mmHg/mL). Acute treatment with MYK-581 alleviated LVOT obstruction (0% vs. 38%), normalized contractility (FS: −7±2%), and increased systolic/diastolic chamber dimensions (e.g., LVIDd: +13±4%) (all P<0.05), while reducing EDP (15±2 to 13±2 mmHg, P<0.05), suggesting acute improvement in ventricular distensibility. Indeed, MYK-581 treatment reduced end-diastolic stiffness (Eed: 0.48±0.11 vs. 0.36±0. 10 mmHg/mL, P<0.05) and normalized trans-mitral motion patterns during filling. Conclusions Bred cats, homozygous for the A31P MYBPC3 variant, presented a cardiac phenotype that models multiple characteristics of the human oHCM phenotype including dynamic LVOT obstruction. Acute treatment with the mavacamten surrogate, MYK-581, not only alleviated hypercontractility and LVOT obstruction, but improved ventricular filling and end-diastolic pressures. Taken together, these pre-clinical observations show potential salutary effects beyond obstruction relief in patients with HCM. Funding Acknowledgement Type of funding source: Private company. Main funding source(s): MyoKardia

Biomechanics of diastolic dysfunction: a one-dimensional computational modeling approach

This study uses a complete and validated computational model of the cardiovascular system to simulate the two main pathologies involved in diastolic dysfunction (DD), i.e., abnormal active relaxation and increased ventricular diastolic stiffness. The three phenotypes of DD were successfully replicated according to literature data. We elucidate the biomechanical effect of the relaxation pathologies involved and how these pathologies interact to create the various phenotypes of DD.