View clinical trials related to Heart Failure NYHA Class III.
Filter by:The goal of this randomized, controlled, open-label, interventional study is to evaluate whether, in patients with heart failure (HF) and iron deficiency (ID), the administration of vitamin D in combination with sucrosomial iron is as effective as intravenous ferric carboxymaltose in improving symptoms of HF. The main hypothesis which the study aims to test is the non-inferiority of sucrosomial iron (± vitamin D) compared with FCM treatment, after 24 weeks. Primary endpoint: the performance of the Six-Minute Walking Test, comparing the mean difference from baseline of the distance walked by patients in meters. Participants will be evaluated in outpatient scheduled visits at 6, 12 and 24 weeks, performing blood tests, clinical evaluation, instrumental investigations and recording any adverse events, cardiovascular events, re-hospitalizations and fractures. The study will involve randomization into 3 groups with a 1:1:1 ratio: 1. Control group [standard of care]: administration of FCM (Ferinject®) with a dose between 500 and 2000 mg (depending on body weight and hemoglobin values), to be administered in 1 or 2 doses (time 0 ± 6 weeks) with possible additional administration of 500 mg at week 12 in case of persistent ID. 2. Sucrosomial iron group: administration of sucrosomial iron (SiderAl Forte®) at a dose of 60 mg (2 tablets) once a day for 24 weeks. 3. Sucrosomial iron and vitamin D group: administration of sucrosomial iron (SiderAl Forte®) at a dose of 60 mg (2 tablets) once daily + vitamin D3 (100,000 IU load at time 0, then 2,000 IU daily) for 24 weeks
The goal of this clinical trial is to test the safety of lab-grown heart cells made from stem cells in subjects with congenital heart disease. The main questions it aims to answer are: - Is this product safe to deliver to humans - Is the conduct of this trial feasible Participants will be asked to: - Agree to testing and monitoring before and after product administration - Receive investigational product - Agree to lifelong follow-up Researchers will compare subjects from the same pool to see if there is a difference between treated and untreated subjects.
Ischemic heart disease (IHD) leads the global mortality statistics. Atherosclerotic plaques in coronary arteries hallmark IHD, drive hypoxia, and may rupture to result in myocardial infarction (MI) and death of contractile cardiac muscle, which is eventually replaced by a scar. Depending on the extent of the damage, dysbalanced cardiac workload often leads to emergence of heart failure (HF). The atrial appendages, enriched with active endocrine and paracrine cardiac cells, has been characterized to contain cells promising in stimulating cardiac regenerative healing. In this AAMS2 randomized controlled and double-blinded trial, the patient's own tissue from the right atrial appendage (RAA) is for therapy. A piece from the RAA can be safely harvested upon the set-up of the heart and lung machine at the beginning of coronary artery bypass (CABG) surgery. In the AAMS2 trial, a piece of the RAA tissue is processed and utilized as epicardially transplanted atrial appendage micrografts (AAMs) for CABG-support therapy. In our preclinical evaluation, epicardial AAMs transplantation after MI attenuated scarring and improved cardiac function. Proteomics suggested an AAMs-induced glycolytic metabolism, a process associated with an increased regenerative capacity of myocardium. Recently, the safety and feasibility of AAMs therapy was demonstrated in an open-label clinical study. Moreover, as this study suggested increased thickness of the viable myocardium in the scarred area, it also provided the first indication of therapeutic benefit. Based on randomization with estimated enrolment of a total of 50 patients with 1:1 group allocation ratio, the piece of RAA tissue is either perioperatively processed to AAMs or cryostored. The AAMs, embedded in a fibrin matrix gel, are placed on a collaged-based matrix sheet, which is then epicardially sutured in place at the end of CABG surgery. The location is determined by preoperative late gadolinium enhancement cardiac magnetic resonance imaging (LGE-CMRI) to pinpoint the ischemic scar. The controls receive the collagen-based patch, but without the AAMs. Study blood samples, transthoracic echocardiography (TTE), and LGE-CMRI are performed before and at 6-month follow-up after the surgery. The trial's primary endpoints focus on changes in cardiac fibrosis as evaluated by LGE-CMRI and circulating levels of N-terminal prohormone of brain natriuretic peptide (NT-proBNP). Secondary endpoints center on other efficacy parameters, as well as both safety and feasibility of the therapy.
ADLIFE is a EU-funded project developing innovative digital health solutions to support healthcare planning and care delivery for patients with advanced chronic conditions (chronic obstructive pulmonary disease and/or heart disease failure). ADLIFE's technology innovations will be deployed, used and evaluated in seven healthcare environments in Spain, the UK, Sweden, Germany, Denmark, and Israel. ADLIFE intends to impact three stakeholders: patients, informal caregivers and health professionals, and consequently across the seven participating international healthcare systems. ADLIFE intervention aims at slowing down the patients' functional deterioration, ensuring their quality of life and promoting shared decision making, reducing the caregiver burden, and improving the health professional working conditions; all this under the scenario of an improvement in the healthcare resource use. The research aims to prove whether the ADLIFE intervention can deliver appropriate targeted and timely care for patients with severe long-term diseases when applied in real-life settings. Based on a mixed-method approach, the study will provide scientific evidence based on the effectiveness, socio-economic, implementation and technology acceptance assessment of ADLIFE compared to the standard of care (SoC) to provide scientific evidence supporting the funding decision-making of the ADLIFE intervention.
The BEDICARE-HF study aims to go further in the research on digital support. The objectives of this study are to demonstrate the feasibility, acceptability, adoption, sustainability and safety of a of a smartphone-based digital support system in the Belgian healthcare system. It also aims to effectiveness, evaluate the cost of implementation of the system and demonstrate the cost-effectiveness. The study is multi-center, involving the principal investigator, Dr. Pouleur at Cliniques University Clinics Brussels, and co-investigators from 10 hospitals across Belgium. These physicians will enroll 15 patients on Comunicare's online platform. The patients will then have access to the Comunicare application for 6 months, where they will be asked to answer questionnaires and take their vital parameters. They will also have access to documentation on their pathology and will be able to perform videoconferences with their doctor/nurse via the platform. Eligible patients are patients discharged from hospital for cardiac decompensation. At the time of inclusion, patients must be in NYHA (New-York Heart association) class II, III, or IV, with an LVEF (ejection fraction ejection fraction) of ≤50%. The BEDICARE-HF project is based on the standard of care that an HF (heart fealure) patient would receive without being part of any study. No other invasive interventions are additionally planned by the project. The patient data collected by the recruiting physician is secured by Comunicare. These fully anonymized data will be sent to Jessa at the end of the study for statistical and economic economic analysis of the results. The BEDICARE-HF study will therefore investigate the implementation of a digital support intervention for HF supported by smartphone in a European legislative framework. This study will allow further in the evaluation of digital support for HF and to evaluate a low-cost smartphone solution. The results of this study will demonstrate whether and how a smartphone-based digital support system improves self-care capabilities, clinical management, and health outcomes of patients with HF. They will provide important information on the implementation of a implementation of a digital support system in a specific healthcare setting.
In order to determine if NfL can be a prognostic biomarker for VCID, participants will undergo a baseline evaluation consisting of neuropsychological testing and a blood draw with a 12-month follow-up consisting of neuropsychological testing and blood draw. After indicated interest in the study, participants will be screened either in person during a regularly scheduled clinic visit or by phone for eligibility. After consenting, participants will be scheduled for a baseline testing session. One session, lasting about 3 hrs, will include neuropsychological testing and a blood draw. After completion of baseline testing, participants who agree to take part in the clinical trial will begin a 12-week treatment of Ang-(1-7) via daily subcutaneous injections. During the drug treatment, participants will be called weekly to ensure that everything is going well with the injections. After participants have completed the 12-week injection period, participants will be scheduled for a second appointment which will include a blood draw and neuropsychological testing. All participant will be scheduled for a 12-month follow-up, which will include a blood draw and neuropsychological testing. Participants will be called every second month by research staff for a brief update on changes to health status, and to increase compliance with the 12-month follow-up. Our One-Year outcome for this study is to provide early proof-of-concept clinical trial data that will support a larger, more comprehensive NIH funded study on the safety and efficacy of Ang-(1-7) to prevent cognitive impairment in HF patients at risk for developing VCID/ADRD. Our Long-Term outcome is to demonstrate whether plasma NfL exhibits characteristics making it useful as a Prognostic Biomarker to predict cognitive decline in early heart disease-associated VCID and identify pre VCID-symptomatic in individuals with symptomatic HF. Our goal will be to use levels of plasma Nfl as an enrollment enrichment factor in future trials to allow enrollment or stratification of patients more likely to develop VCID or ADRD and be responsive to Ang-(1-7) therapy.
To understand the feasibility of characterizing walking patterns in heart failure subjects and subjects at risk for arrhythmias using an investigational wearable monitor called the SWAN study system.
The study aims to test the diagnostic accuracy of native T1 mapping for the diagnosis of cardiac amyloidosis prospectively. The hypothesis is that native T1 mapping with a cut-off value of 1341ms (3 tesla CMR) in older patients with symptomatic heart failure, increased LV wall thickness and elevated cardiac biomarkers is non-inferior to the reference method to diagnose cardiac amyloidosis (CA). As secondary measure, a web-based ATTR probability estimator for the diagnosis of CA will be evaluated.
The focus of this study is to test the efficacy of a 12-week, phone-delivered Positive Psychology-Motivational Interviewing (PP-MI) intervention, with additional twice weekly PP and health behavior text messages for a total of 24 weeks (with interactive, algorithm-driven, goal-focused text messages in the final 12 weeks), compared to an attention-matched MI-based educational condition, in a randomized trial (NIH Stage II) of 280 patients with New York Heart Association class I-III Heart Failure (HF).
This investigation will evaluate the ability of the Moderato® System to safely and effectively deliver CNT, to reduce sympathetic activity in heart failure patients