View clinical trials related to Ischemia.
Filter by:Hundreds of babies in the world are being treated with brain cooling to prevent brain injury after they lose oxygen at birth. This study will use the newly developed information from the magnet resonance image to determine the actual temperature of the brain. This will enable us to determine if the brain is being uniformly cooled and if techniques that provide cooling need to be changed to improve the injury prevention from cooling.
To determine the effects of whether increasing CNP concentrations slightly above normal will improve the functioning of blood vessels after the interruption in the flow of blood. In this study we are looking at the function of the blood vessels of the forearm, as a substitute for those in the heart
The purpose of this study is to evaluate the safety and tolerability of catheter based injections of VM202 into the heart.
The investigators will determine if the MRI can be used to determine the temperature inside the brain. This is an important piece of information now that cooling the brain is being used to decrease brain damage in infants who had a decrease in brain oxygen or flow around the time of birth.
This study will compare the physiologic responses between exercise stress echocardiography and pharmacologic stress echocardiography on left ventricular volume and wall stress.
The purpose of this study is to determine whether the intravenous administration of single- and multiple-ascending doses of Thymosin Beta 4 is safe and tolerable in healthy volunteers.
The restoration of normal blood flow following a period of ischemia may result in ischemia / reperfusion injury (I/RI), which is characterized by inflammation and oxidative damage to tissues. Varying degrees of I/RI occur upon reperfusion of a donor heart after cold storage. Medications containing antibodies against immune cells have been used for many years as powerful immunosuppressants. These medications, called polyclonal antibody preparations, are generally only used immediately following transplantation and/or to treat rejection. At our institution, one such antibody preparation (Thymoglobulin) is used in most pediatric heart transplant recipients for 3-5 days immediately after transplantation. Because standard immunosuppressive medications (called calcineurin inhibitors) are toxic to the kidneys, the use of Thymoglobulin allows us to delay the initiation of calcineurin inhibitors until the kidneys of completely recovered from the shock of the transplant surgery. We hypothesize that Thymoglobulin may be beneficial in reducing the damage caused by I/RI. Thus, the present study seeks to evaluate the effectiveness of an intra-operative dose of Thymoglobulin (in addition to the standard doses post-operatively) at reducing the effects of I/RI. The study will be a double-bind placebo-controlled trial involving 20 subjects. Biologic markers for I/RI will be assessed at periodic intervals for six months post-transplantation. Subjects receiving intra-operative doses of Thymoglobulin will be compared to the controls in order to assess the effectiveness of intra-operative Thymoglobulin in ameliorating the effects of I/RI.
Silent myocardial ischemia is known to occur in the general medical intensive care unit population immediately following tracheal extubation. We believe these patients are at risk for primary cardiac events in the 4 hours immediately following extubation. Metoprolol is a selective beta-1 antagonist, with little to no beta-2 activity at low and moderate doses. The cardioprotective effects of beta blockade have been well documented in randomized controlled trials. In patients undergoing extubation, prophylactic use of intravenous metoprolol may reduce post-extubation ischemia events as well as precursors of cardiogenic pulmonary edema (atrial and ventricular wall tension). Our primary hypothesis is that prophylactic metoprolol (titrated to reduce resting heart rate by at least 10%) prior to tracheal extubation will reduce the rate of ischemia as judged by ST segment analysis.
This study will determine the safety of 500mg of aspirin added to IV TPA at standard doses to prevent re-occlusion of cerebral vessels after successful reperfusion. In ischemic stroke brain arteries are occluded either by an embolus originating in the heart or large vessels leading to the brain or by a process of acute thrombosis of the cerebral arteries over a ruptured atherosclerotic plaque. Rupture of the plaque exposes thrombogenic elements within the plaque and leads to accumulation and activation of platelets and induction of the clotting cascade eventually leading to acute thrombosis and occlusion of the artery. TPA is currently approved by the Food and Drug Administration to treat heart and brain problems caused by blockage of arteries. It activates plasminogen and leads to disintegration of the thrombus/embolus. It is effective only if begun within 3 to 4.5 hours of onset of the stroke because of potential deleterious side effects including life threatening symptomatic intracranial hemorrhage (sICH) when the drug is administered outside of this time window. Reperfusion of the ischemic brain (i.e. timely opening of the occluded artery) with TPA is associated with improved outcome. However, in about 33% of patients that have successfully reperfused after TPA the artery re-occludes within the first few hours resulting in worsening neurological symptoms and worse functional outcome. This re-occlusion is speculated to result from re-thrombosis over an existing ruptured atherosclerotic plaque. This is explained by the relatively short half life of TPA leaving the exposed ruptured plaque intact which leads to re-activation of platelets and clotting factors and re-thrombosis. Thus, we hypothesize that the addition of an antiplatelet agent to TPA would result in lower rates of re-occlusion after AIS. The FDA approved TPA for patients with AIS but discouraged the concomitant use of anti-platelet or anti-thrombotic drugs for the first 24hours after administration of TPA because of concerns that such therapy may result in increased rates of intracerebral hemorrhage. Aspirin is a well known platelet anti-aggregant that works by inhibition of cycloxygenase 1 and reduction in thromboxane A levels. It has a rapid onset of action and additional potential beneficial anti-inflammatory effects in patients with AIS. The international stroke study showed that acute treatment of stroke patients with 500mg of aspirin is safe and feasible and results in better outcome. Furthermore, the drug was safe in these circumstances with an ICH rate of only . Therefore, the purpose of this clinical trial is to examine the safety and efficacy of the combination of aspirin with rt-TPA in patients with AIS.
Pilot study of continuing aspirin versus switching to clopidogrel after stroke or transient ischemic attack.