View clinical trials related to Dilated Cardiomyopathy.
Filter by:Study evaluates the relationships between daily physical activity levels (PAL) and functional capacity (VO2peak) in patients with dilated cardiomyopathy (DCM)
The heart beat is controlled by electrical signals. Following a heart attack, part of the heart muscle dies and is later replaced by scar tissue. Within this area of scar, there often remain "channels" of surviving tissue still able to transmit electrical signals. However, it is well established that these "conduction channels" (CC) can form a short circuit around the scar, leading to electrical disturbances (arrhythmias) that are potentially life threatening. The commonest of these is ventricular tachycardia (VT), and is estimated to cause 300,000 deaths per year. One recognised treatment option of VT involves burning (ablation) these "conduction channels" (CC) within the scar. However, at present, the procedure is long and is far off 100% effective. Consequently, current best practice does not rely on treating the VT, but rather preventing it from causing sudden death - this is achieved with an Implantable Cardioverter Defibrillator (ICD), a device which can recognise when a patient is in VT and deliver an internal shock to restore the normal electrical conduction. Patients with defibrillators subsequently are subject to recurrent painful and debilitating shocks which, although lifesaving, significantly reduce their quality of life. The limitation with ablation at present is due to the difficulty in visualising these CC's. Investigators at Imperial College have created a novel electrogram visualisation program, Ripple Mapping (RM), which they have already found to be superior to currently used programmes in cases of arrhythmias in the upper chambers of the heart (the atria). During a retrospective study in patients with scar related VT following a heart attack, when ablation was delivered in areas associated with identified Ripple Mapping Conduction Channels, these patients remained free of VT recurrence for >2 year follow up interval. The study hypothesis is that Ripple Mapping can identify all conduction channels within scar tissue critical to the VT circuit, ablation of which will lead to long-term freedom from VT and ICD therapies. The investigators now aim to perform a prospective randomised study comparing Ripple Mapping guided VT ablation against conventional VT ablation.
This will be a cross-sectional, observational study. Null hypothesis: There is no difference in the amount of extracellular volume (ECV or scarring) in the hearts of patients with heart failure as compared to control subjects. Heart failure occurs when the heart muscle has become too weak to work properly. It is associated with an increase in the amount of connective tissue (collagen) which replaces dead heart muscle cells (scarring). Currently a biopsy of the muscle is the only way to measure the amount of scarring. This is invasive and rarely done in children. Because of this, it is difficult to measure the amount of scarring in a particular patient or disease process, which is important for improving our understanding and treatment of the disease. Cardiac magnetic resonance imaging (MRI) is a non-invasive imaging tool which is routinely used to look at areas of local scarring in heart muscle. Because the scarring is so widespread in paediatric patients, we have not been able to use this method previously. Now new imaging techniques allow us to look at widespread scarring but these have not yet been validated in children. We plan to use late gadolinium enhancement (T1 mapping) to measure the amount of scarring in patients with heart failure (we have evidence that their heart biopsies show increased amounts of scar tissue) and children having MRI scans for other reasons. We will use measures of function including echocardiography and 6 minute walk test to compare to the amount of scarring. This will help us to know whether the amount of scarring will be clinically useful. We will look at the amount of various proteins in the blood of patients and control subjects which are related to the scarring and cell death processes. We already use blood tests to monitor heart failure and these tests may help us to refine our testing and improve timing of treatment (e.g. transplantation). This study will help us to design further research in this field.
The purpose of this study is to determine the genetic basis of cardiomyopathies and heart failure.
- Chronic severe mitral regurgitation can lead to symptoms and left ventricular dysfunction. - The purpose of this study is to prospectively follow patients with non-ischaemic cardiomyopathy who are eligible for mitral valve repair surgery and primarily measure the quality of life through the Minnesota Living with Heart Failure Questionnaire & the Kansas City Cardiomyopathy Questionnaire.