101 Clinical Trials for Various Conditions
The STABLE-VT trial aims to determine the safety profile and clinical efficacy of a modified approach to ventricular tachycardia (VT) ablation that integrates myocardial scar as visualized on cardiac magnetic resonance (c-MRI) or CT into electroanatomical mapping (EAM) for VT ablation.
This clinical study will utilize a new cell therapy approach (Human embryonic stem cells derived cardiomyocytes or hESC-CMs) to improve survival and cardiac function in patients with chronic left ventricular dysfunction secondary to MI (Myocardial Infarction).
To test the specific research questions, healthy men and age-matched healthy premenopausal females will be enrolled. Subjects will undergo cardiac magnetic resonance imaging and spectroscopy (MRI/MRS) to evaluate cardiac morphology/function and fat metabolism. To acutely elevate myocardial triglyceride content, subjects will be asked to abstain from eating for 2 days (reproducibly causes a significant and physiological increase in myocardial fat deposition, transiently). Subjects will be allowed water and/or an isotonic saline solution in order to maintain hydration status. After screening, subjects will meet with the research coordinator or an investigator for a discussion, with opportunity for questions, before applicable consent forms are obtained. The subject will be screened for metal in or on their body and claustrophobia using a standard MR screening form. A venous blood sample will be taken for measurement of metabolic health, circulating hormones, and systemic inflammation. Imaging will include cine imaging for global morphology and function, tissue tagging for regional tissue deformation, spectroscopy for fat quantification. After baseline images of the heart are obtained, the subject will be asked to squeeze a MR-safe handgrip dynamometer at 30% of their maximum while images of the heart are obtained. Blood pressure will also be measured at rest and during stress. Each MRI will take approximately 90-120 minutes. Aim 1 will test the hypothesis that cardiac steatosis induced left ventricular dysfunction is sexually dimorphic, by comparing age-matched men and premenopausal women before and after 48 of fasting. Subjects will complete the MRI/MRS protocol described above before and after the fasting intervention. Aim 2 will test the hypothesis that estrogen is protective against cardiac steatosis-induced dysfunction, by suppressing ovarian sex hormones with a GnRH antagonist and repeating the fasting studies with and without estrogen add-back. 30 female subjects will be treated with GnRH antagonist and repeat the 48 hour fasting intervention and cardiac MRI/MRS protocol. 15 of the subjects will receive estrogen add-back using a transdermal patch, the other 15 subjects will receive a placebo patch. Aim 3 will test whether plasma and myocardial fatty acid composition is sexually dimorphic, by performing comprehensive plasma and myocardial lipidomics assessment.
The goal of this clinical trial is to learn if heart function remains normal after stopping heart failure medication in patients who have received chemotherapy.
This is a single center, open-label trial designed to assess the safety and efficacy of ranolazine (Ranexa) in patients with pulmonary hypertension associated with left ventricular diastolic dysfunction. All patients will receive active drug. The study includes a screening period, 6 month treatment period and a follow up period. Eligible patients who provide informed consent and who meet all inclusion/exclusion criteria will be enrolled in this study. There is neither proven therapy for patients with diastolic dysfunction-associated pulmonary hypertension nor for patients with diastolic dysfunction alone. Ranolazine, an inhibitor of cardiac repolarization (sodium channels), could represent a new and effective treatment of this entity.
Study to evaluate if macitentan is safe and tolerable enough to be used for treatment of subjects with combined pre- and post-capillary pulmonary hypertension (CpcPH) due to left ventricular dysfunction.
Study to determine the safety, tolerability, pharmacokinetics and immunogenicity of single intravenous administrations of GGF2 in patients with heart failure.
Congestive 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.
Heart failure is a progressive disease that decreases the pumping action of the heart. This may cause a backup of fluid in the heart and may result in heart beat changes. When there are changes in the heart beat sometimes an implantable heart device is used to control the rate and rhythm of the heart beat. The purpose of the REVERSE clinical trial is to determine whether pacing in both the left and right ventricles using Cardiac Resynchronization Therapy (CRT) can help slow the progression of heart failure in people who have mild or previous symptoms and poor heart pumping function. This kind of therapy has previously been shown to reduce symptoms and improve exercise capacity in people with more advanced forms of heart failure.
The objective of this study is to assess the effects of intrathecal local anesthetics on left ventricular global longitudinal strain (LVGLS) using transthoracic echocardiography (TTE).
The purpose of this Trial is to demonstrate the safety and effectiveness of the use of Impella 5.5 in high-risk cardiac surgery patients, with the overall aim to evaluate if using Impella 5.5 with SmartAssist (Impella 5.5) peri-operatively improves early hemodynamics, end-organ function and clinical outcomes in patients with severely reduced LV function undergoing cardiac surgery.
The purpose of this research is to prospectively test and validate the single-lead Low EF algorithm in outpatients in order to test the performance of a single-lead ECG based algorithm to identify people with decreased left ventricular EF.
The purpose of this research is to prospectively test and validate the single-lead Low EF algorithm in outpatients in order to test the performance of a single-lead ECG based algorithm to identify people with decreased left ventricular EF.
The purpose of this study is to evaluate how Eko AI performs in the real world, front-line setting where the availability of sophisticated, expensive diagnostic tools is limited, and where there is a premium on detecting VHD early in its course.
The purpose of this study is to assess if using the Impella® CP (or Impella® 2.5) device during high-risk PCI in patients with reduced left-sided heart function will result in an improvement in symptoms, heart function and health after a heart procedure compared to the current standard of care.
The purpose of this research is to prospectively test and validate the single-lead Low EF algorithm in outpatients in order to test the performance of a single-lead ECG based algorithm to identify people with decreased left ventricular EF.
Prospective, multi-center, single arm, post approval study to be conducted in the United States.
Before initiating the full randomized study, a Pilot Safety Phase will be performed. In this phase the composition of cells administered via the Biosense Webster MyoStar NOGA Injection Catheter System will be tested. The randomized portion of the study will be conducted after a full review of the safety data from the pilot Phase by the Data safety monitoring board. Following the Pilot Phase of five (5) Fifty (50) patients scheduled to undergo cardiac catheterization and meeting all inclusion/exclusion criteria will be evaluated at baseline. Patients will be randomized in a 2:2:1 ratio to one of three Treatment Strategies.
Thirty (30) patients with chronic ischemic left ventricular dysfunction secondary to MI scheduled to undergo cardiac catheterization will be enrolled in the study. This is a phase II study intended to gain additional safety and efficacy assessments among two dose levels previously studied in a phase I setting.
The purpose of the INOVATE-HF study is to demonstrate the long-term safety and efficacy of vagus nerve stimulation with the CardioFit® system for the treatment of subjects with Heart Failure.
Heart needs constant supply of energy to continue working. Phosphorus magnetic resonance spectroscopy allows us to measure energy produced in the heart. The purpose of this study is to determine if the energy production is reduced in failing heart.
This study is to collect data and learn more about the Vscan Ultrasound Imaging System. It is an "observational" study with no additional procedures or intervention prescribed other than using the Vscan along with a routine medical physical exam.
More than 1 million Americans suffer heart attacks each year. Although current treatments are able to stabilize the condition of the heart, none is able to restore heart function as it was prior to the heart attack. Adult stem cells, which are immature cells that can become many different types of cells, may offer a potential means of reversing or preventing permanent damage caused by a heart attack. Recent studies have shown promise in using adult stem cells from bone marrow to reverse damage to the heart muscle caused by a heart attack, but more research is needed to assess the safety and effectiveness of stem cell use and to discover the best time to administer treatment. This study will evaluate the safety and effectiveness of using adult stem cell infusions 2 to 3 weeks after a heart attack for improving heart function in people who have had a recent heart attack and a common procedure called a percutaneous coronary intervention (PCI).
Heart attacks are a leading cause of death for both men and women in the United States. A heart attack occurs when blood flow to the heart is restricted, commonly due to a blood clot that has formed in one of the coronary arteries. If the clot becomes large enough, blood flow to the heart can be blocked almost completely and the heart muscle in that area can suffer permanent injury or death. Although a percutaneous coronary intervention (PCI) can be used to open up the blocked artery and restore blood flow to the heart muscle, there may be a significant amount of heart tissue that has been irreversibly damaged. Recent studies have shown that adult stem cells from bone marrow may be able to improve heart function after a heart attack. This study will evaluate the safety and effectiveness of using adult stem cells for improving heart function in people who have had a recent heart attack and a PCI.
To evaluate the safety and effectiveness of the JenaValve Trilogy™ Heart Valve System for transcatheter aortic valve replacement (TAVR) in subjects with continuous flow left ventricular assist devices (cfLVAD) and clinically significant aortic regurgitation (AR) who are indicated for TAVR
The proposed mechanistic trial will test the effect of dietary sodium reduction on cardiac and vascular structure and function in those with elevated blood pressure or hypertension. Findings from this study will fill the knowledge gap on the underlying mechanisms of dietary sodium intake on cardiovascular disease risk in addition to blood pressure and could provide further evidence on sodium reduction for the prevention of cardiovascular disease.
To demonstrate that home-based exercise rehabilitation (HER) compared to usual care (UC) results in a significant reduction in healthcare utilization in HeartMate 3 (HM3) left ventricular assist device (LVAD) patients.(defined as rehospitalization, VAD Clinic visits, and ER visits during the 1st year after index discharge following LVAD implantation).
Studying the causal roles of components of the renin-angiotensin-aldosterone system (including angiotensin-(1-7) (Ang-(1-7)), angiotensin-converting enzyme 2 (ACE2), Ang II, and ACE), uric acid, and klotho in pediatric hypertension and related target organ injury, including in the heart, kidneys, vasculature, and brain. Recruiting children with a new hypertension diagnosis over a 2-year period from the Hypertension and Pediatric Nephrology Clinics affiliated with Brenner Children's Hospital at Atrium Health Wake Forest Baptist and Atrium Health Levine Children's Hospital. Healthy control participants will be recruited from local general primary care practices. Collecting blood and urine samples to analyze components of the renin-angiotensin-aldosterone system (Ang-(1-7), ACE2, Ang II, ACE), uric acid, and klotho, and measuring blood pressure, heart structure and function, autonomic function, vascular function, and kidney function at baseline, year 1, and year 2. Objectives are to investigate phenotypic and treatment response variability and to causally infer if Ang-(1-7), ACE2, Ang II, ACE, uric acid, and klotho contribute to target organ injury due to hypertension.
COLUMBIA CARDS is a pilot study to understand how COVID-19 affects the heart. It is known that COVID-19 can affect the heart in different ways. COLUMBIA CARDS is studying why some COVID-19 survivors develop clinical conditions such as heart inflammation, fluid buildup, blood clots, and other cardiac problems during or after their COVID-19 illness, and why other ones do not. In this study, we will use cardiovascular magnetic resonance (CMR) and transthoracic echocardiography (TTE) to better understand the impact of COVID-19 on the heart.
This is a randomized, prospective, single-blinded trial to determine the overall rate of successful His-Purkinje conduction system pacing Optimized Trial of Cardiac Resynchronization Therapy (HOT-CRT) versus biventricular pacing using coronary sinus lead (BVP) to compare acute and mid-term outcomes. Acute outcomes include change in QRS duration pre-and post-pacing (degree of QRS narrowing) and incidence of major periprocedural complications (pericardial tamponade, need for lead revision, etc.). Mid-term outcomes include echocardiographic response at 6 months along with a composite clinical outcome of heart failure hospitalization, ventricular arrhythmias, crossover, and all-cause mortality.