View clinical trials related to Heart Diseases.
Filter by:Clinical study that aims to evaluate a new strategy using the SYNTAX II Score calculator in the functional assessment of patients with new coronary 3-vessel-disease who undergo percutaneous coronary intervention (PCI)
Ancillary Effects of Dexmedetomidine Sedation After Cardiac Surgery
Positron emission tomography (PET) scans can be used to evaluate whether parts of the heart muscle are alive but receiving inadequate blood supply. This study involves the use of two radiotracers that will measure whether heart muscle cell are alive and quantify the blood supply to the heart muscle.
The autonomic nervous system plays an important role in the precipitation of AF in structurally-abnormal hearts. Restoration of autonomic imbalance may therefore prevent new-onset AF. Renal artery denervation (RDN) is a novel percutaneous procedure that uses radio-frequency energy to destroy the sympathetic renal nerves. Symplicity 1 and -2 studies have shown that RDN effectively reduces blood pressure in up to 80% of treated patients. LVH regression and improvement of diastolic dysfunction follow as a consequence of afterload reduction and renin-angiotensin-aldosterone system modulation. RDN may thus also reduce intra-atrial pressure resulting in less stretch of the pulmonary venous ostia where most ectopic AF-foci originate. Hypothesis: RDN restores autonomic imbalance in HTHD and lowers intra-atrial pressure by reducing afterload. These synergistic mechanisms may prevent new-onset AF.
The purpose of the ISCHEMIA-CKD trial is to determine the best management strategy for patients with stable ischemic heart disease (SIHD), at least moderate inducible ischemia and advanced chronic kidney disease (CKD; estimated glomerular filtration rate [eGFR] <30 ml/min/1.73 m² or on dialysis). This is a multicenter randomized controlled trial of 777 randomized participants with advanced CKD. Participants were assigned at random to a routine invasive strategy (INV) with cardiac catheterization (cath) followed by revascularization (if suitable) plus optimal medical therapy (OMT) or to a conservative strategy (CON) of OMT, with cath and revascularization reserved for those who fail OMT. The trial is designed to run seamlessly in parallel to the main ISCHEMIA trial as a companion trial. SPECIFIC AIMS A. Primary Aim. The primary aim of the ISCHEMIA-CKD trial is to determine whether an invasive strategy of cardiac cath followed by optimal revascularization, in addition to OMT, will reduce the primary composite endpoint of death or nonfatal myocardial infarction in participants with SIHD and advanced CKD over an average follow-up of approximately 2.8 years compared with an initial conservative strategy of OMT alone with catheterization reserved for those who fail OMT. The primary endpoint is time to centrally adjudicated death or nonfatal myocardial infarction (MI). B. Secondary Aims. Major: To compare the incident of the composite of death, nonfatal MI, resuscitated cardiac arrest, or hospitalization for unstable angina or heart failure, and angina symptoms and quality of life, as assessed by the Seattle Angina Questionnaire, between the INV and CON strategies. Other secondary aims include: comparing the incidence of the composite of death, nonfatal MI, hospitalization for unstable angina, hospitalization for heart failure, resuscitated cardiac arrest, or stroke; composite of death, nonfatal MI, or stroke; composite endpoints incorporating cardiovascular death; composite endpoints incorporating other definitions of MI as defined in the clinical event charter; individual components of the primary and major secondary endpoints; stroke and health resource utilization, costs, and cost effectiveness. A major secondary aim of ISCHEMIA-CKD trial is to compare the quality of life (QOL) outcomes-patients' symptoms, functioning and well-being-between those assigned to an invasive strategy as compared with a conservative strategy. In the protocol, angina frequency and disease-specific quality of life measured by the Seattle Angina Questionnaire (SAQ) Angina Frequency and Quality of Life scales, respectively, are described as the tools that will be used to make this comparative assessment. Recent work has indicated that it is possible to combine the information from the individual domain scores in the SAQ into a new Summary Score that captures the information from the SAQ Angina Frequency, Physical Limitation and Quality of Life scales into a single overall score. The advantages of using a summary score as the primary measure of QOL effects of a therapy are a single primary endpoint comparison rather than two or three (eliminating concerns some may have about multiple comparisons) and a more intuitive holistic (patient-centric) interpretation of the effectiveness results. With these advantages in mind, the ISCHEMIA leadership has agreed that the SAQ Summary Score will be designated as the primary way this secondary endpoint will be analyzed and interpreted, with the individual SAQ scores being used in a secondary, explanatory and descriptive role. A key subgroup analysis will be to stratify the results among those with daily/weekly angina (baseline SAQ Angina Frequency score ≤60), monthly angina (SAQ Angina Frequency score 61-99) and no angina (SAQ Angina Frequency score = 100). Condition: Coronary Disease Procedure: Cardiac catheterization Phase: Phase III Condition: Cardiovascular Diseases Procedure: Angioplasty, Transluminal, Percutaneous Coronary, other catheter-based interventions Phase: Phase III Condition: Heart Diseases Procedure: Coronary Artery Bypass Surgery Phase: Phase III
Mechanisms that typically result in increased cardiac output, such as inotropic support, increased heart rate, and decreased afterload, have a blunted effect in Fontan circulation. The "thoracic pump" is a contributor to venous return that has been largely unexplored in patients with Fontan physiology. Inspiratory muscle training can improve the performance of competitive athletes across a range of sports and can improve quality of life and functional capacity in heart failure patients, presumably by reducing inspiratory muscle fatigue and possibly by improving peripheral blood flow during exercise. One could surmise that the effects of these changes would be particularly important in the Fontan population. The investigators propose to study the effects of inspiratory muscle training on exercise and pulmonary function parameters in a cohort of adult Fontan patients. The investigators hypothesize that a 12-week program of inspiratory muscle training with an inspiratory impedance threshold device will improve inspiratory muscle strength and endurance, and that this will translate into improved exercise performance in patients with Fontan physiology.
The purpose of this study is to evaluate the prevalence, during the enrolment, of Left Ventricular Dysfunction diastolic and/or systolic in patients with diabetes mellitus type 2 without known or documented heart disease history and recognize its predictive clinical, biohumoral and with non-invasive techniques parameters.
Acute kidney injury (AKI) occurs in 40% of children following heart surgery. Serum creatinine (Scr) is a late biomarker of AKI, rising 24-48 hours after surgery. Thus, for medicines excreted in the urine, AKI could potentially lead to toxic levels in the blood. Urinary biomarkers have the ability to detect AKI earlier. Whether early detection of AKI through urinary biomarkers can predict altered drug levels is unknown. Milrinone is used to improve heart function after surgery, but accumulates in AKI resulting in low blood pressure. Dose adjustments are not currently possible because of the late rise in SCr, and are based on clinical parameters that may lead to clinically relevant over or under-dosing. Thus, this study will address an important knowledge gap being the first to use elevations of AKI biomarker concentrations to anticipate increased milrinone levels.
The outcome of this research will be a demonstration that family health history (FHH) risk data can be used efficiently to deliver more effective healthcare in geographically and ethnically diverse clinical care environments. Although FHH is a standard component of the medical interview its widespread adoption is hindered by three major barriers: (1) a dearth of standard collection methods; (2) the absence of health care provider access to complete FHH information; and (3) the need for clinical guidance for the interpretation and use of FHH. In addition, the time constraints of the busy provider and poor integration of FHH with paper medical records or electronic medical records (EMR) impede its widespread use. The investigators hypothesize that patient-driven and electronic collection of FHH for risk stratification will promote more informed decision-making by patients and providers, and improves adherence to risk-stratified preventive care guidelines. The study team will use an implementation sciences approach to integrate an innovative FHH system that collects FHH from patients. Intermountain Healthcare will provide the information technology expertise with EMR design to develop an innovative solution to a storage model standard for FHH data as well as a centralized standards-compliant open clinical decision support (OpenCDS) rule development architecture to analyze FHH and to generate evidence-based, individualized, disease risk, preventive care recommendations for both patients and providers.
Recent advances in genomic techniques are making possible a new wave of genetic discovery in congenital heart disease (CHD). Existing data suggests that CHD occur in Sub-Saharan Africa at frequencies similar to the rest of the world. In this application, we propose to utilize the unique advantages of Sub-Saharan Africa - a combination of the most genetically diverse populations in the world and of diminished environmental background effects (i.e. low prevalence of smoking, alcohol abuse, obesity in comparison to western countries) - to better understand the genetic basis for congenital heart disease. We will couple next generation genomic techniques with more traditional gene discovery methods to investigate CHD in two African countries: Uganda and Nigeria. The inclusion of syndromic and non-syndromic CHD observed in these populations as well as careful phenotyping (including echocardiography) will greatly enhance our potential to provide insight into the genetic architecture of CHD in African populations. To accomplish this, we plan to enroll families, in whom members have congenital heart malformations consistent with an error of early human development in our research protocol. Patients will be enrolled at the Uganda Heart Institute in Kampala, Uganda, and at the Department of Pediatrics, College of Medicine, University of Lagos, Nigeria, with the potential to include other African sites. High throughput genomic studies will be done at the NIH.