View clinical trials related to Cardiac Amyloidosis.
Filter by:Cardiac amyloidosis is an increasingly contributor of degenerative cardiac diseases. However, its frequency remains underestimated, and diagnosis is often realized at late stages of the disease. A larger use of clinical and echographic Red Flag signals during routine echocardiographic examination may enhance the identification of early stage of the disease.
The aging of the population is a reality in our society, with a strong increase in the number of elderly patients hospitalized for heart failure in our institutions. Heart failure in these patients is more present than to younger patients, with preserved ejection fraction form (HFpEF). Aging is responsible for the onset of senile amyloid cardiomyopathy. This pathology is still imperfectly understood and its link with the increase in the frequency of HFpEF is important. In addition, specific treatments have just shown their effectiveness. It is therefore urgent to better identify the prognostic predictive parameters of this cardiomyopathy. The pathophysiological involvement of the coronary microcirculation responsible for a true microvascular coronary disease (CMVD) has been described as predictive factor in all cardiomyopathies. However the implementation of preventive strategies and / or therapeutic of the coronary microcirculation dysfunction are limited because we lack of diagnostic tests available and applicable to large cohorts of patients. Our team INSERM U1039 Radiopharmaceutiques Biocliniques in collaboration with the laboratory GIPSA-lab (Grenoble Images Speech Signal Automatique), laboratory specialized in the signal analysis, has developed a new method of analysis allowing to measure the coronary microcirculation dysfunction usable in SPECT thanks to the measurement of a myocardial perfusion heterogeneity index (IHPM) (patented technique). The 3C registry (NCT03479580) is a registry studying the prevalence and cardiovascular prognosis of macro and microcirculatory coronary artery disease using the latest coronary evaluation techniques in patient with cardiomyopathy. This registry deployed on interventional cardiology centers on the Alpine Arc is therefore also addressed to patients with senile cardiomyopathy. The data collected will provide a better understanding of the factors influencing the prognosis of senile cardiomyopathy and the prognostic contribution of the measurement of the IHPM will be evaluated.
Cardiac amyloidosis is a common cause of refractory cardiomyopathy and heart failure in an adult population. There are several types of cardiac amyloidosis, but two are the most common (1): A. AL - Light chain sunset. B. ATTR - Sunset of transthyretin protein. This amyloidosis has two subtypes: 1. Hereditary / familial - due to genetic mutation 2. Senile / Wild-type (WT) - Acquired with age The main goal of this study is to evaluate cardiac amyloidosis imaging efficiency using 18F-NaF PET / CT and quantification of absorption [in standard uptake value SUVs]. and to compare cardiac amyloidosis imaging using 18F-NaF PET / CT and gamma camera imaging with 99mTc-PYP.
The research study is being conducted to test how two different types of Positron Emission Tomography (PET/CT) scans could be used to image a type of heart disorder called amyloidosis (AL). There will be two groups in the study. One group will have PET/CT scans using an imaging drug called 18F-NOS and the other group will have PET/CT scans using a drug called Florbetaben. subject will be assigned to one of the groups when she/he agrees to be in the study.
Although being classified as a rare disease, cardiac amyloidosis constitutes an increasing cause of heart failure, which is often overlooked and thus poorly managed. Amyloidosis involves deposits of light chain immunoglobulins in the immunoglobulin light chain amyloidosis (AL) type, but it may also be of a hereditary type in mutated transthyretin amyloidosis (ATTRm) or of a senile type in wildtype transthyretin forms (ATTRwt). Myocardial biopsy remains a gold standard for definitive diagnosis but it is a traumatic technique which only provides information on a limited number of sampled sites. Useful but not fully specific signs of cardiac amyloidosis may also be provided by Magnetic Resonance Imaging or MRI (delayed retention imaging) and echocardiography (longitudinal strain pattern). Notwithstanding the above, relatively specific markers of amyloid plaques are now available in Positron Emission Tomography (PET). These markers are primarily fluorinated tracers which have been developed for the diagnosis of Alzheimer's disease. Two of these have already been the subject of feasibility studies in the setting of cardiac amyloidosis diagnosis, on a maximum of 10 amyloidosis patients but with very favorable results. The hypothesis is that one of these two tracers, Florbetaben labelled with Fluorine-18-Florbetaben (18F-Florbetaben) used in the study, has sufficiently strong and prolonged binding kinetics at the level of the amyloid plaques to allow: (i) achieving whole-body PET recordings and thus, (ii) identifying not only cardiac amyloidosis but also extracardiac binding sites, particularly those readily accessible to biopsy sampling. This hypothesis has been strengthened by a recent case report illustrating the ability of whole-body florbetaben-PET to image not only cardiac but also extra-cardiac sites of amyloid deposits (Clin Nucl Med. 2017;42(1):50-3).
Aortic stenosis (AS) is the most common valvular heart disease. Once symptomatic with severe AS, outcome is poor unless the valve is replaced surgically or via transcatheter aortic valve replacement (TAVR). Transthyretin amyloid (ATTR) deposits are common in the heart muscle in up to 25% of octogenarians, and after an asymptomatic period of unknown duration, cause overt heart failure and arrhythmias in a proportion of cases. The prevalence and impact of covert ATTR amyloidosis in elderly individuals with AS are unknown. Detection would avoid misdiagnosis, guide treatment and, potentially, improve outcomes. Recent data have shown that echocardiography, cardiovascular magnetic resonance (CMR), computed tomography (CT), and DPD scintigraphy, can identify ATTR amyloid deposits, but the clinical performance of these various tests is unknown. This study will investigate elderly patients with symptomatic severe AS using imaging to explore ATTR amyloid in AS and determine its prevalence and impact on outcome. The investigators aim to recruit a total of 250 patients aged 75 or older being considered for intervention for severe AS. The prevalence of cardiac amyloid will be assessed in three arms (sAVR, TAVI and medical therapy, with a likely patient ratio of 50:150:50), using five investigation modalities - all cohorts (echocardiography and DPD scintigraphy); sAVR cohort (biopsy and CMR); TAVI cohort (EqCT); medical therapy only cohort (as per work-up/trial prior to no intervention decision). The primary outcome measure is patient mortality. Secondary outcomes measures are major adverse cardiovascular events, length of stay, pacemaker implantation, ECV measured by EqCT and CMR. Follow up will be at 1-year with clinical echocardiogram (for sAVR and TAVI patients) and/or telephone interview for all patients (if not carried out in person at the time of the echocardiogram).
To prove the organ-reversing potential of thalidomide for amyloidosis with cardiac involvement
The aim of the study is to evaluate coronary flow reserve (CFR), index of microcirculatory resistance (IMR), and proportion of overt microvascular disease, defined as depressed CFR as well as elevated IMR in patients with cardiac amyloidosis. The second objective of this study is to compare results of non-invasive test including serum light chain amount, Doppler echocardiography with 2D strain, and cardiac perfusion MRI. The third object of this study is to evaluate the association between physiologic indices and pathologically measured percent area involvement of interstitium.