View clinical trials related to Hypertrophic Cardiomyopathy.
Filter by:Hypertrophic Obstructive Cardiomyopathy (HOCM) is an inherited cardiac condition which causes the heart muscle to become abnormally thick causing obstruction of blood flow in the heart. This causes debilitating symptoms including shortness of breath, blackouts and chest pain. Current treatments are not ideal as the medication is often poorly tolerated or ineffective. People with HOCM can often have an Implantable Cardioverter Defibrillator (ICD) to shock them out of dangerous arrhythmias. ICD's can also be used as pacemakers and are a promising treatment option, since they can alter the sequence of the heart muscle contraction thereby relieving the obstruction to the blood flow, making it easier for the heart to pump. The study will recruit patients who already have an ICD/pacemaker or who are scheduled to have an ICD / pacemaker implanted. For patients who are due to have a device implanted high precision haemodynamic, echocardiographic and electrical measurement techniques will be used to assess whether adjusting the position of the pacing lead (at the time of implant) can bring about changes in LVOT gradient and blood pressure. These patients with a new device and also patients who already have a device in situ will then go on to have atrioventricular delay (AV Delay) optimisation so we can assess what the optimum AV delay should be programmed at in order to bring about the most improvement in LVOT gradient and blood pressure. Patients will then be recruited into a medium term double blinded randomised crossover study. They will have optimum RV pacing settings turned on for 3 months. They will then return and be crossed over and have optimum RV pacing turned off for a further 3 months. The primary outcome will be to see if optimum RV pacing being turned on is effective in improving symptoms and quality of life.
The proposed intervention will be administration of empagliflozin at a standard dose of 10 mg daily for a period of 12 months. Patients with diagnosed diabetes will be excluded from the study. Patients (n = 250) will be randomized in a double-blind fashion to empagliflozin or placebo group. The primary endpoint of the study will be the change in peak oxygen uptake (VO2 max) measured in a cardiopulmonary exercise test. VO2max is an objective indicator of physical performance and will be evaluated before and after empagliflozin or placebo treatment.
With stress echo (SE) 2020 study, a new standard of practice in stress imaging was developed and disseminated: the ABCDE protocol for functional testing within and beyond CAD. ABCDE protocol was the fruit of SE 2020, and is the seed of SE 2030, which is articulated in 12 projects: 1-SE in coronary artery disease (SECAD); 2- SE in diastolic heart failure (SEDIA); 3-SE in hypertrophic cardiomyopathy (SEHCA); 4- SE post-chest radiotherapy and chemotherapy (SERA); 5- Artificial intelligence SE evaluation (AI-SEE); 6- Environmental stress echocardiography and air pollution (ESTER); 7- SE in repaired Tetralogy of Fallot (SETOF) ; 8- SE in post-COVID-19 (SECOV); 9: Recovery by stress echo of conventionally unfit donor good hearts (RESURGE); 10- SE for mitral ischemic regurgitation (SEMIR); 11- SE in valvular heart disease (SEVA); 12- SE for coronary vasospasm (SESPASM). The study aims to recruit in the next 5 years (2021-2025) ≥10 000 patients followed for ≥5 years (up to 2030) from ≥20 quality-controlled laboratories from ≥10 countries. In this COVID-19 era of sustainable health care delivery, SE2030 will provide the evidence to finally recommend SE as the optimal and versatile imaging modality for functional testing anywhere, any time and in any patient.
There is existing data in the literature that suggests an additional predictive value of three dimensional ECG with respect to the presence of electrical abnormalities and for an existing cardiac disease. Especially regarding patients who suffered from a myocardial infarction in the past (post MI patients), evidence has been provided for a potential association of 3D repolarisation abnormalities and incidence of sudden cardiac death (SCD). In addition, there is some vague evidence of so called 3D ECG and prediction of coronary artery disease. This 3D ECG device is using the technology of 3D ECG vector loops and is assessing the variability of these ECG vector loops in the 3-dimensional space. Based on these data, the parameters of 3D ECG are suggested to carry certain value to predict or to identify individuals already suffering from a cardiac disease or being at risk experiencing a cardiac event in the future. In this context we performed a preliminary study with 3D-ECG device in healthy volunteers evaluating the robustness of this method with respect to reproducibility, intra- and intra-observer variability which could be confirmed. We thus postulate that the 3D ECG technology might bear the potential to serve as a sufficient screening method for diagnosing cardiomyopathy in patients with an unknown heart failure etiology.
The aim of this randomized trial is to compare the improvement in exercise capacity among patients with highly symptomatic hypertrophic obstructive cardiomyopathy despite optimal medical treatment who undergo alcohol septal ablation (ASA) or surgical septal myectomy (SSM).
This study is designed to quantify the ventricular stasis in patients with different forms of cardiomyopathy and at risk of stroke (ischemic, non-ischemic dilated cardiomyopathy and hypertrophic cardiomyopathy) by post-processing of 2D color Doppler echocardiography and phase contrast-magnetic resonance images in order to establish the relationship between quantitative variables of intraventricular stasis and the prevalence of silent embolic events and/or intraventricular mural thrombosis.
This study aims to identify and assess new CMR techniques that can improve current CMR protocols.
Hypertrophic Cardiomyopathy (HCM) is the most common inherited heart muscle condition affecting up to 1 in 200 of the general population. It results from mutations in genes encoding components of the contractile apparatus in the heart muscle cell (myocyte). These mutations result in increased energy cost of force production for the myocyte which then cumulatively causes a myocardial energy deficit. This myocardial energy deficit is then thought to lead to cardiac hypertrophy ('left ventricular hypertrophy' or LVH) in HCM. LVH leads to impairments in heart muscle function, heart muscle oxygenation and microvascular blood flow and is the chief driver of patient symptoms in HCM. These symptoms consist of chest pain, shortness of breath, dizziness, fainting episodes or palpitations. Occasionally, the disease may cause sudden cardiac death (SCD). HCM is the most common cause of SCD in young people including competitive athletes. In addition, HCM has been found to result in significant global deterioration in health-related quality of life. Treatment of HCM has focused on relief of symptoms by drugs such as ß-blockers which slow the heart rate and improve heart function. However, symptom relief is often incomplete and there is no evidence on the benefit of ß-blockers or related medications to reverse LVH. Perhexiline, a potent carnitine palmitoyl transferase-1 (CPT-1) inhibitor shifts myocardial metabolism to more efficient glucose utilisation and rectifies impaired myocardial energetics. It is currently used to treat angina in patients with coronary artery disease. There is some preliminary evidence that Perhexiline may aid in the improvement of symptoms in patients with HCM. However, the effect of any form of therapy on potential regression of LVH in HCM remains unexplored. In this randomised double-blind placebo-controlled trial, the investigators will use state of the art cardiac imaging, principally advanced echocardiography and Cardiovascular Magnetic Resonance (CMR) to study the effects of perhexiline on LVH, cardiac function, and oxygenation in symptomatic patients with HCM. The investigators hypothesize that perhexiline will favourably reduce LVH and improve myocardial oxygenation by improving myocardial energetics, and that these putative morphological and functional changes can be accurately measured utilizing echocardiography and CMR. If this pilot study supports the hypothesis, then it will pave the way for a major randomised controlled trial to definitely determine the role of Perhexiline in HCM.
Hypertrophic Cardiomyopathy (HCM) is an inherited heart condition. Most people who have it are unaware of any problems relating to it. Unfortunately, a small number of people with the condition can suddenly develop a dangerous fast heart beat that can lead to death. There is no cure, but implanting a cardioverter-defibrillator (ICD), which is like a pacemaker can save the life of affected individuals. However, ICD implantation has its own problems, so choosing who gets an ICD is a very important decision. The current approach for recommending people for an ICD has limitations and a better method is needed. Investigators have developed a new technique called the 'Ventricular Conduction Stability' (V-CoS). This involves wearing a special vest which records electrical signals from the heart, and then running on a treadmill. Investigators have used it to identify abnormalities in the hearts of people with (HCM) who have also survived a life-threatening event. This project aims to test new tool against current methods to ascertain which is better at identifying patients who should have an ICD.
The purpose of this research study is to understand more about various heart rhythms (electrical problems) in persons with hypertrophic cardiomyopathy with and without sleep apnea.