The Impact of Zinc Supplementation on Left Ventricular Function in Nonischemic Cardiomyopathy
Heart FailureCardiomyopathiesHeart failure affects over 5.3 million Americans and, while other cardiovascular diseases have enjoyed a reduction in mortality rates over the last decade, the mortality from heart failure continues to rise[1]. Thus, identifying novel therapies that can reduce heart failure development and/or progression are warranted. Unifying to most cardiomyopathic processes is an impaired handling of reactive oxygen species (ROS)[2-4]. Reactive oxygen species are generated as byproducts of inflammation and oxidative stress that occur in the setting of normal myocardial aerobic metabolism. Metallothionein, glutathione reductase, and superoxide dismutase are major antioxidants in the myocardium that help combat oxidative stress and prevent myocardial damage. In certain clinical settings, including cardiac ischemia, diabetes, and heavy metal excess (copper, iron), myocardial oxidative stress levels are greatly increased. When pro-oxidant levels exceed myocardial antioxidant capabilities, ROS-induced membrane, protein, and DNA inactivation can lead to the development of cardiac dysfunction. One means of preventing the development or progression of cardiomyopathy is to reduce oxidative stress through up-regulation of intramyocardial antioxidants. Murine studies of cardiomyopathy have shown that oral administration of zinc acetate may succeed as an indirect myocardial anti-oxidant because zinc sufficiently up-regulates the intramyocardial production of superoxide dismutase (a zinc-dependant anti-oxidant enzyme) and metallothionein (a "super antioxidant") [5-8]. Zinc also directly reduces prooxidant Cu levels by reducing gastrointestinal zinc absorption. However, to date, no studies have examined the impact of zinc acetate supplementation in subjects with cardiomyopathy and systolic failure on antioxidant capacity and remodeling. The hypothesis of this pilot study is that administration of oral zinc acetate to humans with cardiomyopathy will lead to an up-regulation of myocardial anti-oxidant capabilities,leading to a favorable reduction in oxidative stress. This study will provide preliminary data to support a randomized, placebo-controlled trial of zinc therapy in heart failure as a means of improving or preventing the progression of systolic dysfunction in subjects with mild-moderate heart failure.
Statin Therapy for Ischemic and Nonischemic Cardiomyopathy
Cardiovascular DiseaseCardiomyopathy3 moreThe purpose of this study is to see if taking a cholesterol lowering drug Lipitor (Atorvastatin Calcium)will increase the number of endothelial progenitor cells (EPC's) circulating in the blood of heart failure patients taking this cholesterol-lowering drug, and if this will also show an improvement in the damaged areas of the patient's hearts as documented by MRI scans.
Clinical Evaluation on Advanced Resynchronization
Heart FailureCardiomyopathyThe aim of the study is to compare clinical benefits of the cardiac resynchronisation (CRT) achieved by the PEA optimised pacing configuration and a CRT optimised by standard clinical procedure. PEA optimised configuration (PEA-CRT) is obtained, during patient's follow-up, using the Peak Endocardial Acceleration sensor features onboard the device.
Efficacy and Safety Study of Genetically Targeted Enzyme Replacement Therapy for Advanced Heart...
Heart FailureCongestive1 moreThe study is divided into 2 parts. In the first part, the safety of the gene transfer agent MYDICAR® will be evaluated. In the second part, the ability of MYDICAR® to improve heart function will be studied.
PACMAN - PAcing for CardioMyopathies, a EuropeAN Study
Heart FailureThe purpose of this study was to evaluate the benefit of biventricular pacing in patients with heart failure who were receiving optimal pharmacological therapy, and who were either with or without an ICD indication
Betaferon/ Betaseron (Interferon Beta-1b) in Patients With Chronic Viral Cardiomyopathy
CardiomyopathiesHeart DiseasesChronic viral cardiomyopathy is a disease where the cardiac muscle is attacked by a virus and this may result in a reduction in the output of the heart (pump function) thereby causing complaints such as chest pain, shortness of breath and palpitations. Betaferon (interferon beta-1b) is marketed for the treatment of Multiple Sclerosis already, but until now, it has not been proven whether it is also effective in patients with chronic viral myocardial disease. This study will be conducted to examine the efficacy and safety of Betaferon in patients with this disease. The aim of the treatment is to eliminate the virus from the heart so that the heart function and clinical status can gradually improve.
Perhexiline Therapy in Patients With Hypertrophic Cardiomyopathy
Hypertrophic CardiomyopathyHypertrophic Cardiomyopathy (HCM) is a relatively common inherited heart muscle disease. Many patients experience symptoms of breathlessness, fatigue and chest pain. These symptoms are not always controlled with current therapies. Recently the investigators showed that a drug called Perhexiline markedly improved exercise capacity and symptoms in patients with heart failure. In this proposal the investigators wish to test whether Perhexiline improves exercise capacity and relieves symptoms in patients with HCM
Biventricular Pacing In Patients With Left Ventricular Dysfunction After Cardiovascular Surgery...
CardiomyopathyHeart Failure2 moreCongestive heart failure (CHF) is a medical condition that is due to left ventricular systolic dysfunction (LVSD). LVSD is a decreased ability of the heart to pump blood forward. There are 5 million people in the United States that have CHF and 52,828 new cases are diagnosed annually. There are 995,000 hospital visits and 52,828 deaths annually due to CHF. Previous studies have shown that people with this condition are at a higher risk for complications immediately after any type of heart surgery than are normal individuals. This includes increased dependence on medications and devices to improve the pumping function of the heart and blood pressure. Additionally, they also have longer lengths of hospital stay and higher rates of death compared to normal individuals. Some patients with LVSD not only have a decreased pumping ability of the heart, they also have an inefficient pumping function. These patients have been shown to benefit from a device therapy known as biventricular pacing. Biventricular pacing involves simultaneously electrically stimulating the two major pumping chambers of the heart known as ventricles using a pacemaker and wires. This causes a more coordinated contraction of the heart chambers resulting in improvement in the pumping ability of the heart and blood pressure. Studies have confirmed that in these patients, implantation of a biventricular pacemaker improves patients' symptoms and quality of life as well as decreasing a need for future hospitalizations. Whether biventricular pacing in patients with LVSD improves patient outcomes after heart surgery has not been investigated. Some patients temporarily develop slow heart rates after cardiovascular surgery. These slow heart rates can cause a decrease in the blood pumped from the heart and result in low blood pressures. Therefore, all patients undergoing cardiovascular surgery, regardless of left ventricular function, receive temporary pacing wires that are placed on one of the ventricles during the surgery. Temporary pacing will result in an increase in heart rate and improvement in the amount of blood pumped by the heart and in blood pressure. The placement of these wires is precautionary as only a few patients need to be paced for slow heart rates. Once patients are felt to no longer require them, the wires are easily removed. The purpose of this study is to determine whether biventricular pacing immediately after heart surgery in patients with LVSD will improve in-hospital outcomes. Patients that are scheduled for heart surgery and meet the inclusion criteria will be approached for consent to participate in this study. Once consented, they will be randomized to one of three treatment arms: usual care, RV pacing (single ventricle pacing), or biventricular pacing. Randomization is a process similar to picking numbers out of a hat. The patients will then undergo surgery as scheduled. During the surgery, the patients will receive the temporary pacing wires on both ventricles instead of one. Immediately after surgery, the patients will receive either usual care, RV pacing, or biventricular pacing depending upon the treatment arm that they were randomized to. The pacing wires will be removed as soon as the patients become stable as per routine. The clinical, operative, and in-hospital characteristics of these patients will be recorded on specialized forms. The characteristics of those that received biventricular pacing will be compared to those that had RV or no pacing to see whether there was any benefit to this mode of therapy.
Cyclosporine A to Treat Hypertrophic Cardiomyopathy (HCM)
CardiomyopathyHypertrophic1 moreThis study will examine the effectiveness of the drug cyclosporine in treating hypertrophic cardiomyopathy (HCM), a condition in which the heart muscle thickens. The thickened muscle can impair the heart's pumping action or decrease its blood supply, or both. Various symptoms, such as chest pain, shortness of breath, fatigue, and palpitations, may result. In animal studies, cyclosporine prevented heart muscle from thickening in mice that had been engineered to develop thick hearts. Patients with HCM 18 to 75 years old are screened for this study under protocol 98-H-0102 and this protocol. Screening tests include blood tests, echocardiogram to measure heart thickness, Holter monitor to record heartbeats, treadmill exercise test, and various imaging tests including a thallium scan, radionuclide angiography, magnetic resonance imaging (MRI), and cardiac catheterization to examine heart function and blood supply. Patients admitted to the study will be randomly assigned to take either cyclosporine tablets or a placebo (a look-alike tablet with no active ingredient) twice a day for 6 months. During a brief hospital stay at the start of the study, blood samples will be taken to measure cyclosporine levels. After discharge, heart rate and blood pressure will be checked and blood tests done during follow-up visits once a week for 2 weeks and then every two weeks until the end of the 6-month treatment period. At that time, patients will be hospitalized a second time for repeat tests to determine the effects of the drug on the heart condition. They include thallium scan, radionuclide angiogram, MRI, treadmill exercise test, cardiac catheterization, and echocardiogram. An echocardiogram and MRI will be repeated 1 year after the start of the study to evaluate long term effects of the drug, if any.
The Effect of Metoprolol in Patients With Hypertrophic Obstructive Cardiomyopathy.
Hypertrophic CardiomyopathyHypertrophic obstructive cardiomyopathy (HOCM) patients often develop disabling symptoms of heart failure. Current treatment strategies are predicated on the empirical use of long-standing drugs, such as beta-adrenergics, although with little evidence supporting their clinical benefit in this disease. Metoprolol is currently the most widely used beta-blocker in symptomatic HOCM patients, but a randomized, placebo-controlled trial, that looks at the effect in HOCM patients has never been conducted. No studies of HOCM combine invasive pressure measurement with exercise and echocardiography. All previous studies, both invasive and echocardiographic, have been conducted during rest, and not during exercise. Symptoms of HOCM patients are function-related, and exercise testing is essential to assess the condition and the effect of drugs.