View clinical trials related to Pulmonary Arterial Hypertension.
Filter by:This is a multicenter, randomized (2:1 oral treprostinil: placebo), double-blind, placebo-controlled study in subjects with Pulmonary Arterial Hypertension (PAH) who are currently receiving background dual therapy (ambrisentan, tadalafil) for at least 30 days at randomization for their PAH. Once randomized, subjects will return for 5 study visits up to Week 28 during the blinded period. After the Week 28 Visit, eligible subjects will transition to the open-label period of the study for up to 20 weeks.
A double-blinded, placebo-controlled study of Dimethyl fumarate (DMF) in 34 Systemic Sclerosis-Pulmonary Hypertension (SSc-PAH) patients. The study will determine safety and the primary outcome variability for DMF in treating SSc-PAH; the primary outcome of clinical efficacy in this pilot trial will be improvement in 6-minute walk distance (6MWD).
It is recognized that patients with various forms of heart and lung disease exhibit varying degrees of pulmonary hypertension, pulmonary vascular remodeling, and right ventricular dysfunction. The genetic, molecular, and cellular processes driving these phenomena are not well understood. Rapid advances in high throughput omic methodology, combined with powerful bioinformatics and network biology capability, have created the opportunity to conduct studies that broadly search for homologies and differences across the spectrum of disease states associated with pulmonary hypertension, and determinants of the spectrum of right ventricular compensation that accompanies these conditions
The purpose of the study is to document the effect of first line dual oral combination therapy with macitentan 10mg and tadalafil 40mg on pulmonary vascular resistance (PVR) in treatment-naïve patients with newly diagnosed pulmonary arterial hypertension (PAH).
Many control mechanisms exist which successfully match the supply of blood with the metabolic demand of various tissues under wide-ranging conditions. One primary regulator of vasomotion and thus perfusion to the muscle tissue is the host of chemical factors originating from the vascular endothelium and the muscle tissue, which collectively sets the level of vascular tone. With advancing age and in many disease states, deleterious adaptations in the production and sensitivity of these vasodilator and vasoconstrictor substances may be observed, leading to a reduction in skeletal muscle blood flow and compromised perfusion to the muscle tissue. Adequate perfusion is particularly important during exercise to meet the increased metabolic demand of the exercising tissue, and thus any condition that reduces tissue perfusion may limit the capacity for physical activity. As it is now well established that regular physical activity is a key component in maintaining cardiovascular health with advancing age, there is a clear need for further studies in populations where vascular dysfunction is compromised, with the goal of identifying the mechanisms responsible for the dysfunction and exploring whether these maladaptations may be remediable. Thus, to better understand the etiology of these vascular adaptations in health and disease, the current proposal is designed to study changes in vascular function with advancing age, and also examine peripheral vascular changes in patients suffering from chronic obstructive pulmonary disease (COPD), Sepsis, Pulmonary Hypertension, and cardiovascular disease. While there are clearly a host of vasoactive substances which collectively act to govern vasoconstriction both at rest and during exercise, four specific pathways that may be implicated have been identified in these populations: Angiotensin-II (ANG-II), Endothelin-1 (ET-1), Nitric Oxide (NO), and oxidative stress.
Exercise capacity (EC) is limited in pulmonary arterial hypertension (PAH) by impaired right ventricular (RV) function and inability to increase stroke volume (SV). Disease targeted therapy, increases EC by improving SV. Additional factors may contribute to exercise limitation: - Peripheral and respiratory muscle dysfunction - Autonomic dysfunction - An altered profile of inflammation - Mitochondrial dysfunction. The enhancement of EC achieved pharmacologically may therefore be limited. Exercise training in PAH improves EC and quality of life (QOL). The changes in physiology responsible for this improvement are not clear. Patients with PAH stable on optimal oral therapy, but not meeting treatment goals, will be enrolled in a 30-week randomised exercise training program. One arm will undertake training for 15 weeks (3 weeks residential, 12 outpatient), the other will receive standard care for 15 weeks then 15 weeks training. Aims: 1. Demonstrate that exercise training can enhance EC and QOL when added to optimal drug therapy a UK PAH population. 2. Explore mechanisms of exercise limitation and factors that improve with training, assessing: - Cardiac function - Skeletal muscle function - Autonomic function - Respiratory muscle strength - Serum and muscle profile of inflammation Primary outcomes (15 weeks) 1. 6 minute walk distance 2. QOL 3. RV ejection fraction
The investigators are doing this research study to find out how blood flow changes in the lungs of people with pulmonary hypertension before and after treatment with ambrisentan (sold under the brand name Letairis). The investigators hope that knowing about these differences will help us to better understand pulmonary hypertension and find new ways to diagnose it earlier.
This is a long-term open-label safety extension to the Phase 2a study of inhaled QCC374 in adult patients with PAH. This study provides the patients who completed the QCC374X2201 study with the option to continue receiving QCC374. The study will monitor the long-term safety, tolerability and efficacy of QCC374 in patients with PAH.
This is a prospective, multicenter, open-label, randomized, controlled, parallel Phase 3 study with an open-label single-arm extension period to evaluate pharmacokinetics (PK), safety and efficacy of macitentan in children with pulmonary arterial hypertension (PAH).
This was a non-confirmatory, randomized, placebo controlled, subject and investigator blinded study of QCC374 in PAH subjects. The study was planned to have 2 Parts: Part 1, an initial safety cohort with a 0.03 mg bid starting dose, and Part 2, a larger cohort with a 0.06 mg bid starting dose. However, due to early study termination following Part 1, Part 2 was not completed. Both study parts were comprised of four phases: a screening period for up to 28 days, a titration period of 2 weeks, a stable dose period of 14 weeks and safety follow-up period for 28 days. At the end of the treatment period of 16 weeks, eligible patients were given the option to participate in a separate long-term extension study (CQCC374X2201E1 (NCT02939599)), where all patients were treated with an individual optimal dose of QCC374.