View clinical trials related to Heart Diseases.
Filter by:SCORE is an active, prospective, non-randomized, multi-center outcome-oriented registry of patients implanted with St Jude Medical (SJM) market-released cardiac rhythm management (CRM) products. This registry will be conducted in the United States (US). The primary purpose of the registry is to evaluate and publish acute and long-term performance of market-released SJM CRM products by analyzing product survival probabilities. Product status and any related adverse events will be collected to measure survival probabilities.
The purpose of the study is 1> to compare neointimal stent coverage after OCT-guided vs. Angio-guided PCI, 2> to compare neointimal stent coverage at 3 months after EES vs BES implantation, 3> to determine the duration of dual antiplatelet therapy by OCT measurement at 3 months
This study will test whether lowering the delivery of excess fats to the heart in persons with type-2 diabetes mellitus improves heart muscle function. The investigators will also test whether specific lipid molecular species in plasma can serve as biomarkers for diabetic heart disease.
Macrophage migration inhibitory factor (MIF) is a pleiotropic cytokine that promote the inflammatory response.In animal studies, it has been found that MIF is released in the ischaemic heart, promoting glucose uptake and protecting the heart from ischaemia-reperfusion injury.The MIF concentration, influenced by age and myocardial ischemia, have different impact on myocardial functional recovery after ischemia.Therefore, the purpose of this experiment is to study the clinical significance of MIF in patients with coronary heart disease.
The purpose of this study is to evaluate the impact of implementing a universal pulse oximeter screening as a way to detect critical congenital heart disease in otherwise well-appearing newborns.
Objectives: Despite utilization of available means for cardioprotection during cardiac surgery, myocardial injury still occurs. Further improvement of cardioprotection is therefore necessary. Remote ischemic preconditioning (RIPC) is an easy and non-invasive method. Laboratory research has shown promising results regarding myocardial survival during open heart surgery, but the clinical value of RIPC is still largely unknown. The investigators hypothesize that RIPC before coronary artery bypass grafting (CABG) reduces the incidence of postoperative atrial fibrillation (POAF).
In 2012, infants having surgery for congenital heart disease have a high survival. The investigators are now focused on improving how sick these infants become after surgery (short term outcomes) and their later neurodevelopment (long term outcomes). During heart surgery, cardiopulmonary bypass (CPB; the heart-lung machine) takes over heart function while the surgeon repairs the heart disease. During this surgery there are periods of time when the amount of blood going to the heart and brain is lower than usual, called "ischemia". Once the surgery is finished the blood going to the heart and brain is increased to normal again, called "reperfusion". This ischemia-reperfusion can cause injury to the heart, brain, and other organs, affecting the short and long term outcomes in these infants. Adult studies have shown that a short time of ischemia to the legs for 5-10 minutes [the legs are not damaged by a short time of ischemia, unlike the heart or brain], before severe ischemia to another distant vulnerable vital organ [like the heart or brain], can protect this other vital organ from ischemia-reperfusion injury. This is called "remote ischemic preconditioning" (RIPC). Our objective is to test whether RIPC before heart surgery can improve the recovery of the heart and brain after heart surgery in newborn babies with congenital heart disease. The investigators will test whether RIPC will result in lower peak lactate and troponin levels on the day after heart surgery. Lactate levels are a marker for how much the different tissues of the body suffer from ischemia-reperfusion injury. Troponin is released from damaged heart during ischemia-reperfusion. In our trial infants will be randomized to RIPC or control. This means each baby has an equal chance of being in one group or the other. The intervention group will have RIPC before surgery; the "control group" will not. The investigators hope this trial will lead to a larger study to test if RIPC results in fewer days on a breathing machine after surgery, lower mortality, and higher scores on neurodevelopmental tests at 2 years of age.
Percutaneous coronary intervention (PCI) for the treatment of coronary bifurcation lesion (BL) remains a challenging task. The DK-crush have been established as a safe and efficacious dual-stenting technique, which can effectively improve the success rate of final kissing balloon inflation (FKBI) and reduce long-term major adverse cardiac events (MACE). However, in the clinical real world, especially when the bifurcation angle was relatively small, the DK-crush still has several limitations, such as kissing unsatisfied (KUS), relatively complex wiring or rewiring technique, incomplete stent coverage in the distal side of the side-branch ostium and near the carina, severe stent deformation or evenly acute stent destruction. Our observational study showed that the DK-culotte was also a safe and feasible dual-stenting technique and was equal to DK-crush in terms of improving FKBI and MACE. Nonetheless, there remain no studies for head-to-head comparison of clinical outcomes between the two approaches. We, thereby, carry out a multicentre, non-inferior, randomized and controlled trial to compare DK-culotte stenting versus DK-crush stenting in the treatment of true BL.
To study whether renal sympathetic denervation(RSD) will reduce the all-cause mortality and the recurrence rate of a composite of cardiovascular event(including angina, myocardial infarction, repeat percutaneous coronary intervention and coronary artery bypass grafting) in patients after percutaneous coronary intervention(PCI). Besides whether RSD can reduce the risk factors for coronary heart disease.
This study will test if inhalation of Carbon Monoxide (CO) will increase the numbers of mitochondria in heart muscle. Mitochondria are the small components of muscle and other cells that convert fuel and oxygen to the easily usable forms of energy (ATP) that power all cell's activities. Adequate numbers of healthy mitochondria are essential to heart cell function. From animal and other studies we have reason to believe that breathing small amounts of CO will signal the body to increase the numbers of mitochondria in heart cells. We propose to test this theory in heart valve surgery patients by examining a small sample of heart tissue (from the right atrial appendage) that is routinely cut out during the preparation of the patient for cardio-pulmonary bypass and that would otherwise be discarded by the surgeon. Muscle samples from two groups of subjects will be compared. One group will breath CO and the other group will breath room air. If CO is effective, we should notice an increase in the numbers of mitochondria in the group that was exposed to CO compared to the group that breathed room air.