Active clinical trials for "Pulmonary Arterial Hypertension"

The purpose of this study is to investigate the influence of physical training on exercise capacity, quality of life, functional class, oxygen consumption and right ventricular function in patients with severe associated pulmonary arterial hypertension (APAH) as part of a congenital heart defect with / without Eisenmenger's Syndrome

The study aim is to monitor, during exercise tests carried out in various conditions, the alveolar dead space, by means of continuous transcutaneous measurement of Pt CO2, which would be used as a surrogate for arterial PaCO2. Validity of this measurement needs to be assessed against arterial sampling (either arterial, or arterialized capillary), especially with regards to the lag time required by the CO2 diffusion from the arterial compartment (PaCO2) to the cutaneous one (PtCO2), in particular when rapid changes of CO2 might be induced by exercise. The evaluation will be done in 2 different settings: intensive care patients, equipped, for their routine clinical care, with an arterial line; this allows for a precise timed comparison between PaCO2 and PtCO2 readouts; routine exercise test, where blood gas evaluation is done essentially by means of arterialized earlobe capillary sampling. Following assessment of validity of the measurement (and the lag time PaCO2-PtCO2 which might be necessary to introduce as a correction), evolution of dead space during excise test will be tested in different conditions: Healthy subjects, patients with Chronic Obstructive Pulmonary Disease (COPD), chronic heart failure (CHF), hyperventilation, Pulmonary artery hypertension (PAH), or interstitial lung disease (ILD)

Pulmonary arterial hypertension (PAH) is a type of high blood pressure in the arteries that carry blood from the heart to the lungs. PAH occurs when the openings in the blood vessels of the lungs get smaller and smaller. These smaller openings can be caused by the following: The walls of the arteries tightening The walls of the arteries becoming stiff and narrow from an overgrowth of cells The increased pressure in the pulmonary arteries strains the right side of the heart and it begins to fail, causing difficulty breathing and other symptoms. As PAH progresses, symptoms get worse. There is no cure for PAH, but several medications like endothelin receptor antagonists (ERAs), prostacyclin analogues (PCAs) and riociguat, a soluable guanylate cyclase stimulator, are available to help slow the progression of changes in the pulmonary arteries and help reduce symptoms. Riociguat can be taken together with ERAs and PCAs. In this study, the researchers want to learn about how well riociguat works, how safe it is when patients take it in 1 of these ways: alone with ERA with PCA with ERA and PCA The dosage for each patient will be decided by their doctor. The researchers will review information collected from the patients who have decided with their doctor to start riociguat treatment for their PAH. The study will include about 500 patients in the United States who are at least 18 years old. All of the patients will have either just started taking riociguat or will have been taking it for less than 3 months No investigational products will be administered in this study. Patients will be treated with the Standard of Care (SOC) for PAH. The SOC is the currently appropriate treatment in accordance with scientific evidence and agreed upon in collaboration between medical experts for PAH. There will be no study-mandated visits or treatments. The patients will be in the study for up to 2 years. During this time, they will visit their doctor every 3 to 6 months as part of the Standard of Care. At these visits, the patients will answer questions about their PAH symptoms and whether they have any medical problems. They will also do exercise tests to see how well they are able to breathe and how tired they get while exercising. The doctors will perform other usual examinations which are part of the Standard of Care such as echocardiograms (images of the heart to show how the heart is working) and a right heart catheters (to measure the pressures in the heart) and will take the usual blood and urine samples.

Throughout the past twenty years, numerous specific pharmacologic agents targeting the endothelial dysfunction associated with PAH have emerged. Short term placebo-controlled randomized trials assessing PAH-specific monotherapy with these molecules have reported improvements in pulmonary hemodynamics and exercise capacity. A recent meta-analysis also documented a reduction in short-term mortality of about ≈40% with such therapies. Several randomized clinical trials evaluating PAH-specific combination therapy have been conducted. Our recent meta-analysis showed that combination therapy was associated with a 35% risk reduction for the occurrence of clinical worsening compared to monotherapy. Nonetheless, the investigators also showed 17% of PAH patients receiving combination therapy still experienced clinical worsening over a median exposure of 16 weeks. Moreover, long-term survival on PAH-specific also therapy remains poor in the modern era, with a yearly mortality rate of 15 % in incident idiopathic PAH. The identification of innovative therapeutic targets and validation of these complementary therapeutic interventions are thus urgently needed in PAH. The investigators and others (K. Stenmark, University of Colorado and H. Bogaard, VU University Medical Center, Amsterdam, personal communications), have published strong evidence that BRD4 plays a key role in the pathological phenotype in PAH accounting for disease progression and showed that BRD4 inhibition can reverse PAH in several animal models. Intriguingly, coronary artery disease (CAD) and metabolic syndrome are more prevalent in PAH compared with the global population, suggesting a link between these diseases. Interestingly, BRD4 is also a trigger for calcification and remodeling processes and regulates transcription of lipoprotein and inflammatory factors, all of which are important in PAH and CAD. Apabetalone, an orally available BRD4 inhibitor, is now in a clinical development stage with a good safety profile. The overall objective of the study is to explore the efficacy and safety of apabetalone as an add-on therapy for adult PAH patients and to inform the conduct and the design of a Phase 3 trial. The primary objective of the study is to assess the efficacy of apabetalone as evaluated by the change in PVR over a period of 24 weeks compared to placebo in adult subjects with PAH on stable background therapy. Secondary objectives include changes at week 24 in 6MWD, plasma NT-proBNP concentration, WHO functional class, ESC/ERS risk stratification score, health-related quality of life and additional hemodynamic data from right heart. Exploratory objectives are to evaluate the effects of apabetalone compared to placebo in adult subjects with PAH on mortality and clinically relevant morbidity events, and on circulating levels and transcription changes in whole blood markers of metabolism, vascular calcification, inflammation, DNA damage and leucocyte expression of BMPR2.

This trial is a single-center, Phase 1, placebo-controlled, double-blind, multiple-dose study in two ascending dose cohorts of healthy subjects. The primary objective of the trial is to assess the safety and tolerability of multiple doses of MN-08 tablet administered for 6.5 consecutive days in healthy subjects.

In this study, hyperpolarized 129Xe MRI will be used to evaluate treatment efficacy in patients with pulmonary arterial hypertension (PAH). Participants will be imaged at 4 timepoints (baseline, 6 weeks post-therapy initiation, 12 weeks, and 18 weeks). Images will be analyzed to develop new biomarkers and to understand treatment effects.

Pulmonary arterial hypertension (PAH) and chronic thromboembolic pulmonary hypertension (CTEPH) are severe clinical conditions that, despite advances in therapeutics over the past 20 years, lead to serious morbidity and mortality. Guidelines on the diagnosis and treatment of pulmonary hypertension (PH) recommend the use of a multiparametric risk stratification tool to determine severity of disease, which should guide initial therapy and therapy modulation. This multiparametric risk stratification schema includes objective assessment of exercise capacity, right ventricular function and hemodynamic parameters in order to classify patients into severity categories. Cardiac index (CI) and right atrial pressure (RAP), measured via right heart catheterization (RHC), are the hemodynamic parameters used in risk assessment of PH. Arguably, stroke volume index (SVI) is the most important hemodynamic parameter for assessment of PH severity and there is currently no validated method for noninvasive measurement of cardiac output (CO), CI or SVI. Currently, a major obstacle in the field is that hemodynamic measurements are not obtained on a regular basis in the risk assessment and therapy modulation of patients with PAH and CTEPH. If a noninvasive method of hemodynamic measurement could be correlated with other objective measurements of risk assessment, it could become an invaluable tool in therapy initiation and modulation in the ambulatory setting. This is a single center study to evaluate the use of non-invasive measurement of CO and stroke volume to assess risk and response to treatment in patients with PAH and non- operable CTEPH. We anticipate to enroll a total of 100 subjects at Ronald Reagan UCLA Medical Center. A maximum of 10 hour in total for the study including the consent process, pre-procedure care, RHC procedure, and follow up visit. The initial visit will be approximately 4 hours with the RHC procedure itself will only be 20 minutes. Each follow up visit will be 1.5 hour. Patients with known or suspected PAH or CTEPH will undergo a RHC as part of his or her standard of care. Three techniques of CO measurement will be performed sequentially at the time of the RHC. The device that will be used is the Edwards ClearSight system and EV1000 clinical platform, a device that measures NIBP. Patients will be followed over the period of 1 year every 3 months to obtain serial measurements for six-minute walk distance (6MWD), World Health Organization (WHO)/New York Heart Association Functional Class (FC), B-type natriuretic peptide (BNP) or N-terminal-pro hormone BNP (NT-proBNP), and non-invasive hemodynamic measurements. Additional visits will be scheduled to obtain the serial measurements one month prior and one month following if a patient is initiating or changing PH-specific therapy. As this is a study looking at the feasibility of non-invasive measurement of cardiac output and stroke volume for risk assessment and response to therapy in pulmonary arterial hypertension (PAH) or chronic thromboembolic pulmonary hypertension (CTEPH), study personnel performing the study procedures will not be blinded to the clinical diagnosis and the management of the subject.

IntelliStent is intended to achieve reduction of pulmonary hypertension, improvements in symptoms and quality of life in adolescent and adult patients with congenital heart disease and dilated cardiomyopathy.

Group A will be training group and group B will be control group. Deep breathing exercises will be done as baseline treatment in both groups. Both groups will be assessed with Modified Borg scale, 6-PBRT and Fatigue severity scale at the baseline. The control group patients will perform functional active alternating movements for the upper limbs at home involving three sets with 10 repetitions and a rest interval between 1- and 2-minute. Intervention will be for 3 times a week or 6 weeks. The treatment group patients will perform upper extremity aerobic exercises by using an arm ergometer under the supervision of a physiotherapist. Training intensity will adjust according to 50 80 % of max HR or intensity of dyspnea to 4 points on modified Borg scale (MBS) for at least 15 45 min, 3 times/week over 6 weeks.

To study the effect of SOT in patients with pulmonary vascular diseases (PVD) defined as pulmonary arterial hypertension or chronic thromboembolic pulmonary hypertension (PH) who permanently live >2500m on pulmonary artery pressure (PAP) and other hemodynamics by echocardiography and in relation to blood gases at 2840m with and without SOT.