View clinical trials related to Right Heart Failure.
Filter by:This is a Phase 2, single-center, randomized placebo controlled trial of valsartan (an angiotensin receptor blocker) in adults with pulmonary arterial hypertension. The study will evaluate the safety and clinical efficacy of a 24-week course of valsartan.
Acute Respiratory Distress Syndrome (ARDS) is often complicated by Right Ventricular Dysfunction (RVD), and the incidence can be as high as 64%. The mechanism includes pulmonary vascular dysfunction and right heart systolic dysfunction. Pulmonary vascular dysfunction includes acute vascular inflammation, pulmonary vascular edema, thrombosis and pulmonary vascular remodeling. Alveolar collapse and over distension can also lead to increased pulmonary vascular resistance, Preventing the development of acute cor pulmonale in patients with acute respiratory distress. ARDS patients with RVD have a worse prognosis and a significantly increased risk of death, which is an independent risk factor for death in ARDS patients. Therefore, implementing a right heart-protective mechanical ventilation strategy may reduce the incidence of RVD. APRV is an inverse mechanical ventilation mode with transient pressure release under continuous positive airway pressure, which can effectively improve oxygenation and reduce ventilator-associated lung injury. However, its effect on right ventricular function is still controversial. Low tidal volume (LTV) is a mechanical ventilation strategy widely used in ARDS patients. Meta-analysis results showed that compared with LTV, APRV improved oxygenation more significantly, reduced the time of mechanical ventilation, and even had a tendency to improve the mortality of ARDS patients However, randomized controlled studies have shown that compared with LTV, APRV improves oxygenation more significantly and also increases the mean airway pressure. Therefore, some scholars speculate that APRV may increase the intrathoracic pressure, pulmonary circulatory resistance, and the risk of right heart dysfunction but this speculation is not supported by clinical research evidence. In addition, APRV may improve right ventricular function by correcting hypoxia and hypercapnia, promoting lung recruitment and reducing pulmonary circulation resistance. Therefore, it is very important to clarify this effect for whether APRV can be safely used and popularized in clinic.we aim to conduct a single-center randomized controlled study to further compare the effects of APRV and LTV on right ventricular function in patients with ARDS, pulmonary circulatory resistance (PVR) right ventricular-pulmonary artery coupling (RV-PA coupling), and pulmonary vascular resistance (PVR).
Prospective evaluation of the predictive value for post-LVAD right ventricular failure (RHF) of pulmonary vasodilator challenge, in addition to current laboratory, echocardiographic and haemodynamic parameters. LVAD candidates satisfying the inclusion criteria will undergo vasodilator challenge with sodium nitroprusside (NTP) infusion following the study protocol. Thereafter, we will evaluate all data in order to determine which variables significantly correlate with RHF onset after LVAD implantation.
The Pforzheim Tricuspid Valve Registry study is designed to confirm the safety and performance of the TriClip™ device in a contemporary real-world setting in critically ill patients. The observational trial is a prospective, single arm, open-label, single-center, post market registry.
RV dysfunction has been associated with increased mortality in the ICU and cardiac surgical patients. Thus, early identification of RV dysfunction at less severe stages will allow for earlier intervention and potentially better patient outcomes. However, so far, no studies have reported prospectively the prevalence of abnormal RV pressure waveform during cardiac surgery and in the ICU. The investigator's primary hypothesis is that the prevalence of abnormal RV pressure waveform occurs in more than 50% of cardiac surgical patients throughout their hospitalization. Those patients with abnormal RV pressure waveform will be more prone to post-operative complications related to RV dysfunction and failure in the OR and ICU.
The primary purpose of this study is to investigate the evolution of Right Ventricular (RV) function before and after left ventricular assist device (LVAD) implantation, using novel echocardiographic quantification of RV size and function in combination with comprehensive hemodynamic, laboratory and clinical parameters. The findings of the study will enhance prediction of early and late development of postoperative right-sided heart failure (RHF) and subsequent mortality and morbidity. The secondary purpose of the study is to combine echocardiographic, hemodynamic, laboratory, and clinical data to define optimal management strategies of RHF after LVAD implantation.
The goal of this interventional crossover study, in intubated and mechanically ventilated Acute Respiratory Distress Syndrome (ARDS) patients, is to compare two positive end-expiratory pressure (PEEP) titration techniques regarding: respiratory mechanics, gas exchange, changes in aeration, ventilation/perfusion matching its impact on cardiac function, especially the right heart (RH). The PEEP titration techniques are: PEEP selection based on low PEEP/high FiO2 table ("PEEPARDSnet") and lung recruitment maneuver (LRM) plus PEEPdec titration based on the best compliance of the respiratory system("PEEPLRM").
The use of Impella RP is safe, feasible and provides a hemodynamic benefit in patients with right ventricular failure.