View clinical trials related to Mitral Regurgitation.
Filter by:This study investigates the hypothesis that diffuse interstitial cardiac fibrosis develops in response to chronic volume overload from severe degenerative mitral regurgitation. The investigators will investigate the functional (exercise) and symptomatic (PROMS) outcomes of patients with severe but asymptomatic mitral regurgitation who have the option of choosing surgical repair or watchful waiting.
Percutaneous mitral valve repair (PMVR) with the MitraClip® system has emerged as a therapeutic alternative to surgical valve repair in patients who are at high risk and unsuitable for surgery. The PMVR procedure is typically performed under general anaesthesia, but the MitraClip® is also feasible in deep sedation. The aim of this study is to investigate the safety of deep sedation in patients undergoing the PMVR procedure and to evaluate how deep sedation in comparison to general anaesthesia influences procedural time and in-hospital stay.
Prospective, multi-center, single arm registry. Clinical follow-up at discharge, 30 days, 6, 12, 18 and 24, months, and 3, 4 and 5 years. Concurrent Control (CC) group identified retrospectively from the patients screened for the HRR who did not enroll; patient survival determined at 12 months. NCT00209274 (EVEREST II RCT) Intended use Percutaneous reduction of clinically significant mitral regurgitation in symptomatic patients who are considered to be high risk for operative mortality (high surgical risk).
Prospective, multicenter, continued access registry of the MitraClip® Cardiovascular Valve Repair System in the treatment of mitral valve regurgitation. Patients will undergo 30-day, 6-month, 12-month, 36-month and 60-month clinical follow-up. The study consists of two arms: a High Risk group (NCT01940120) and a Non-High Risk group (NCT00209274) . Patients that did not meet REALISM High Risk or Non-High Risk eligibility criteria were evaluated for consideration for either Emergency Use (EU) or Compassionate Use (CU).
To evaluate the performance and safety of the Cardioband Adjustable Annuloplasty System for repair of functional mitral regurgitation.
Our main hypothesis is that inhalation of milrinone can reduce the elevated pulmonary arterial pressure due to severe mitral valve regurgitation without compromising systemic hemodynamics. Therefore, the effects of a brief inhaled milrinone (IH) on pulmonary artery pressure are determined and compared to those of intravenous milrinone (IV) in severe mitral regurgitation patients undergoing mitral valve surgery.
This Study is designed to observe the clinical outcomes of patients requiring mitral repair that were treated with the CE certified Cardinal System.
The use of minimally invasive cardiac surgery has progressed over the last 5-10 years to allow access to the heart through a small incision in the right chest. This avoids the use of a sternotomy incision through the bone in the front of the chest. The benefits of such an approach are cosmetic (smaller incision not easily visible) and faster recovery. The minimally invasive approach also eliminates the risk of sternal wound infection. Minimally invasive cardiac surgery however poses additional challenges; one of the biggest is access to the large blood vessels which need to be cannulated to allow the heart lung machine to function. In conventional surgery, these vessels are easily accessed as they are entering or leaving the heart. In minimally invasive surgery, the cannula are placed into easily accessible arteries and veins, traditionally the femoral vessels. These vessels are smaller than those by the heart and so require smaller cannula, which provide challenges to the heart lung machine. One way around this is to use more cannulae and so cannulation of a vein in the neck is also performed. This cannula however, has been associated with neck hematoma, tearing of the vein and blood loss. While placement of the cannula in the neck is routine at LHSC now, when this surgery was first performed here 10 years ago, it was done so without the neck cannula and with no injury to patients. The purpose of this study therefore, is to more rigorously study the effect of the neck cannula on heart lung bypass, and more specifically to see if oxygen delivery to the organs, and the brain in particular is sufficient to avoid hypoxia.
Cardiopulmonary exercise testing (CPET) is a safe, noninvasive investigation where a patient walks on a treadmill or cycles whilst attached to an ECG and with a mask that measures the air breathed in and out. It has numerous clinical uses, such as diagnosing the main cause in patients with breathlessness, deciding on timing for heart transplantation and assessing whether patients are safe for a general anaesthetic. A patient's peak oxygen consumption, the maximum amount of oxygen taken up by the blood from the lungs when breathing increases during exercise, is the main measurement taken from CPET. It is low in heart disease and has been used to predict the risk of death and therefore plan treatments for patients. However this is also low in numerous other diseases including lung disease; reduced oxygen consumption in patients with two conditions may be wrongly thought to be because of the heart leading to inappropriate action and distress to the patient. Newer measurements of exercise capacity from the same exercise test are better at predicting death in heart failure. We propose that they are more specific for heart failure over other diseases, for example lung disease, when compared with peak oxygen consumption, and are superior when a single best test for heart failure is required. This research aims to identify which measurement of exercise capacity is most specific for heart failure. We will perform the test on many patients with different diseases, and before and after procedures such as the implantation of special pacemakers, and heart valve operations. This should lead to a more accepted use of this investigation and the more appropriate identification of which patient should have which procedure.
The investigators hypothesize that MR in humans is characterized by adrenergic overdrive, reactive nitrogen species, and an antifibrotic phenotype that relate to the severity of adverse LV remodeling prior to surgery and outcome after valve repair.