Active clinical trials for "Heart Failure"

This 3rd phase of the ELEVATE study. The study is collecting data from an implanted CRT-D device to evaluate a new feature for future heart failure devices.

The Boston Scientific Energen family is capable of measuring the respiratory rate trend (RRT) on a daily basis and transmission of data via the Remote Monitoring technology. This may result in early detection of imminent decompensation at a presymptomatic stage. The study will assess the respiratory trends correlation with clinically relevant heart failure events.

The purpose of this observational study is to collect and characterize multiple physiologic data from a broad subset of subjects with acute heart failure (HF) Changes in physiologic data are expected to correlate with 30-day readmission rates in this population

The purpose of this study is to gather information on how doctors program particular settings on cardiac resynchronization therapy implantable cardiac defibrillators (CRT-Ds), to analyze how these settings affect the amount of cardiac resynchronization therapy (CRT) patients receive and to evaluate the therapy approach for converting abnormally fast heartbeats into normal heartbeats. There are no experimental devices or procedures involved in this study.

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. In certain heart failure cases, when the two lower chambers of the heart no longer beat in a coordinated manner, cardiac resynchronization therapy (CRT) may be prescribed. CRT is similar to a pacemaker. It is placed (implanted) under the skin of the upper chest. CRT is delivered as tiny electrical pulses to the right and left ventricles through three or four leads (soft insulated wires) that are inserted through the veins to the heart. People who have a dangerously fast heart beat, or whose heart is at risk of stopping beating, may be in need of an electronic device called an implantable cardioverter defibrillator (ICD). An ICD is implanted surgically just under the skin in the upper chest area and it sends a strong electrical impulse, or shock, to the heart to return it to a normal rhythm. If the heart is beating too slowly or at an abnormal rhythm, an ICD can also pace the heart to return the heart to its normal rhythm. The InSync ICD device can change the timing of when the left and right ventricles of the heart are paced to beat. The purpose of this study is to monitor the long-term performance of the InSync ICD Model 7272 and the InSync Marquis 7277 systems for cardiac resynchronization therapy (CRT).

An original cohort of 43 patients were recruited for analysis of anthropometrics, metabolic profile, skeletal muscle biopsy, echocardiogram at baseline, 3 months and 9 months post bariatric surgery. While all 43 patients reportedly completed 3 and 9 month evaluations, only 15 patients completed 24 month evaluations due to 28 patients unwilling to return. The overarching purpose appears to have been not only evaluation of weightloss, but normalization of metabolic profile over time.

To identify new dilated cardiomyopathy genes by genetic linkage and mutational analyses.

This registry will provide detailed patient demographics and characteristics at the time of enrollment and will also provide data regarding predictors of clinical outcomes such as heart failure decompensation, heart failure hospitalization, NYHA class, and quality of life.

The goals of this research will be to define some of the mechanisms underlying the progression and complications of heart failure (HF) with preserved left ventricular ejection fraction (HFPEF) Aim 1: to evaluate the differences in cardiac structure, function and fibrosis markers through the spectrum of HF stages in order to deepen the understanding of the pathophysiology driving HF progression. Aim 2: to define the mechanisms by which HF risk factors, such as hypertension, diabetes, obesity, and renal insufficiency, interact with age to increase HF risk, and to evaluate the role of precipitating factors such as myocardial ischemia, atrial fibrillation in HFPEF. Aim 3: to determine prognostic factors in HFPEF patients, by following these patients over time. Accordingly the investigators will correlate baseline data (echocardiographic, MRI or biomarkers) with incident cardiovascular events and determine whether these measures provide incremental prognostic information beyond clinical characteristics.

Application of Nanotechnology and Chemical Sensors for Diagnosis of Decompensated Heart Failure by Respiratory Samples. Breath testing, which links specific volatile molecular biomarkers in exhaled breath to medical conditions, is becoming increasingly popular as a non-invasive and potentially inexpensive diagnostic method for various diseases. NA-NOSE performs odor detection from exhaled breath, thus producing a distinct fingerprint for each mixture of analytes. Several studies have been published, stating the advantages of these sensors, leading to promising outcomes in several fields. The NA-NOSE breath test would be fast (examination and results would be obtained within 5-10 min), inexpensive, eventually portable (smaller than desktop computer), non-invasive and free of any side effects.