16 Clinical Trials for Various Conditions
The objective of ENVISION is to evaluate the safety and effectiveness of the Navitor Transcatheter Aortic Valve Implantation (TAVI) System for treating patients with symptomatic, severe native aortic stenosis who are considered intermediate or low risk for surgical mortality.
The purpose of this research is to validate the prototype AI-Flex device. Researchers at Mayo Clinic developed a new a flexible multi-modal bio-sensing device, AI-Flex, with integrated artificial intelligence (AI) capability. Integration of sensing and AI analysis on the same device removes the need for data storage on the cloud for later analysis. The goal of the device is to allow real-time monitoring of patient health and timely intervention based on patient health condition. It is hoped that the proposed flexible device will allow intimate skin contact using ultra-thin (\<10 µm) geometry to reduce or eliminate relative movement between the skin and flexible epidermal sensors even during rapid motion of the subject, which would significantly improve the sensor signal quality for AI analysis.
Background: Doctors use computed tomography (CT) to get detailed pictures of the heart. CT uses x-rays to gather raw data. Computers assemble this data to make the images doctors look at. A new computer technique can make higher resolution images from the same CT scans. In this natural history study, researchers will take normal CT images of the heart. They will compare those images to super high-resolution (super high-res) images made with a super-computer. Objective: To improve the quality of heart CT scans by using new methods to create the images. Eligibility: People aged 18 years or older who need a CT scan for heart disease. Design: Participants will have a normal CT scan. A substance will be injected through a tube in their arm. They will lie on a table in a large, donut-shaped machine. An X-ray tube will move around their body, taking many pictures. Researchers will use the normal CT scans to create super high-res images. They may do this at the NIH. They may also send the images to the company that made the CT scanner. Participants personal information will be removed before images are sent to the company. The personal information will be replaced by a code. The super high-res images will be returned to the NIH. Some information will be collected from participants medical records. Researchers will compare the normal scans to the super high-res images. Participants' own doctors will also have a chance to see the super high-res images. Participants' CT pictures will be stored and used for future NIH research.
This is a pilot study of patients undergoing structural heart disease procedures that utilize TEE and fluoroscopic guidance at the New York University (NYU) Langone Medical Center. Patients in this study will undergo their procedure utilizing the TEE/Angio fusion software prototype. This protocol is primarily intended to ascertain the potential utility of the software prototype in the study population and to provide data and feedback to improve the workflow and algorithms of the prototype. As such, a primary outcome variable and statistical analysis plan have not been identified. However, procedural time, measures of radiation exposure (dose area product, total radiation dose, fluoroscopy time), degree of residual valvular regurgitation or paravalvular regurgitation as applicable, and complications will be recorded.
Atrial fibrillation is an abnormal beating of the heart that can lead to stroke or heart failure. Structural heart diseases are conditions that affect the heart valves or heart muscle and can cause permanent heart damage if left untreated. Sometimes people have atrial fibrillation or structural heart disease and do not know it. The purpose of this study is to evaluate two devices that can predict who has or may develop atrial fibrillation or structural heart disease based on the results of an electrocardiogram.
Background: A heart catheterization is a diagnostic heart procedure used to measure pressures and take pictures of the blood flow through the heart chambers. Magnetic resonance imaging (MRI) fluoroscopy shows continuous pictures of the heart chambers that doctors can watch while they work. Researchers want to test this procedure with catheterization tools routinely used in x-ray catheterization called guidewires. Guidewires will help move the heart catheter through the different heart chambers. Guidewires are usually considered unsafe during MRI because MRI can cause a guidewire to heat while inside the blood vessels and heart. Researchers are testing special low energy MRI settings that allow certain guidewires to be used during MRI catheterization without heating. Using these guidewires during MRI may help to decrease the amount of time you are in the MRI scanner, and the overall time the MRI catheterization procedure takes. Objectives: To test if certain MRI settings make it safe to use a guidewire during MRI fluoroscopy. Eligibility: Adults 18 and older whose doctors have recommended right heart catheterization. Design: Researchers will screen participants by reviewing their lab results and questionnaire answers. Participants may give 4 blood samples. Participants will be sedated. They will have a tube (catheter) placed in the groin, arm, or neck if they don t already have one. Patches on the skin will monitor heart rhythm. Special antennas, covered in pads, will be placed against the body. Participants will lie flat on a table that slides in and out of the MRI scanner as it makes pictures. Participants will get earplugs for the loud knocking noise. They can talk on an intercom. They will be inside the scanner for up to 2 hours. They can ask to stop at any time. During a heart catheterization, catheters will be inserted through the tubes already in place. The catheters are guided by MRI fluoroscopy into the chambers of the heart and vessels. The guidewire will help position the catheter.
This study will characterize the accuracy of a commercially available artificially-intelligent stethoscope in determining which childhood murmurs suggest underlying congenital structural heart disease and therefore warrant diagnostic echocardiograms.
This study offers catheter-based treatment of heart or artery disease. This protocol permits treatment of patients with cardiovascular diseases who may not be eligible to participate in current research protocols. The treatment offered in this protocol is not experimental, but rather standard treatment provided in most large referral hospitals in the United States. Patients 18 years of age and older who are candidates for catheter-based treatment of obstructive artery disease, including blocked blood flow in a coronary artery (artery to the heart) or in an artery of the arm, leg, brain or kidney may be eligible for this study. Candidates are screened with a general medical evaluation that may include blood tests, magnetic resonance imaging, and monitoring of heart rate and rhythm. Participants undergo angioplasty or stenting for blockage in an artery to the heart or an artery of the arm, leg, brain or kidney. The procedure uses a balloon-tipped catheter to open the blocked artery and likely requires permanent implantation of a metal tube (stent) to improve blood flow through the vessel. During the procedure, the patient is given a sedative and pain medication, if needed.
The goal of this clinical trial is to determine if a machine learning/artificial intelligence (AI)-based electrocardiogram (ECG) algorithm (Tempus Next software) can identify undiagnosed cardiovascular disease in patients. It will also examine the safety and effectiveness of using this AI-based tool in a clinical setting. The main questions it aims to answer are: 1. Can the AI-based ECG algorithm improve the detection of atrial fibrillation and structural heart disease? 2. How does the use of this algorithm affect clinical decision-making and patient outcomes? Researchers will compare the outcomes of healthcare providers who receive the AI-based ECG results to those who do not. Participants (healthcare providers) will: Be randomized into two groups: one that receives AI-based ECG results and one that does not. In the intervention group, receive an assessment of their patient's risk of atrial fibrillation or structural heart disease with each ordered ECG. Decide whether to perform further clinical evaluation based on the AI-generated risk assessment as part of routine clinical care.
Background: Replacing a valve in the heart can save many people s lives. The procedure is called transcatheter aortic valve replacement (TAVR). In rare cases, a flap of tissue called a leaflet can shift during TAVR; the leaflet may block blood flow to the coronary arteries, which supply blood to the heart muscle. About 50% of people who experience this problem will die. To reduce this risk, doctors will cut this leaflet during TAVR. But the tools used to cut the leaflet were originally designed for other purposes. Using these tools during TAVR can be complicated and risky. Researchers want to make TAVR safer. Objective: To test a new device (TELLTALE) designed specifically for use during TAVR. Eligibility: People aged 21 years and older who are undergoing TAVR and who are at high risk of coronary artery obstruction. Design: Participants will be screened. They will have routine tests that are done before undergoing TAVR. Before the procedure, participants will complete a questionnaire. They will talk about how their heart disease affects their quality of life. Their physical abilities and their risk of stroke will be assessed. Participants will be admitted to the hospital for TAVR. They will be placed under general anesthesia or moderate sedation. The procedure will be performed using the TELLTALE guidewire system. Participants will repeat the tests of their physical abilities after the procedure. They will also repeat the questionnaire about their quality of life. These will be repeated again at a follow-up visit in 30 days. Participants will have a final study visit after 90 days. This visit may be in person or remote.
The investigators are aiming to investigate the association between ejection fraction (EF) determined by echocardiography and signals obtained from Photoplethysmography (PPG) in the general population. The investigators are also aiming to investigate the association between blood pressure and signals obtained from PPG in the general population. Finally, the investigators are also aiming to investigate the association between signals obtained from PPG in the general population to cardioechographic findings such as, valvular heart disease, structural heart diseases, cardiomyopathies, pericardial disease etc.
Background: Patient's freedom from VT after RFA remains non-optimal and it depends on many factors. One of them is the effective reduction of the myocardium with RF energy during the operation. The standardization of the parameters of RF will help to increase the success of the procedure. Hypothesis: Radiofrequency ablation of ventricular tachycardias with high power parameters has comparable safety and leads to greater efficacy (absence of ventricular tachycardias and all types of cardioverter-defibrillator therapies) in the long-term compared with ablation with standard parameters in patients with structural heart disease. Purpose: to evaluate the safety and the efficiency of ablation of ventricular tachycardia in patients with structural heart disease using high power RF energy.
The purpose of this study is to assess the safety and performance of Transcatheter Mitral Valve Replacement (TMVR) system for the treatment of severe, symptomatic mitral regurgitation (MR).
This is a research study to evaluate the electrical properties of heart tissue. The purpose of this study is to determine the impedance (electrical resistance) of different tissues on the outer surface of the heart. This may be important for distinguishing scarred heart muscle from fat that can be seen on the surface of the heart. This information may eventually be utilized in patients that undergo a procedure (called catheter ablation) for the treatment of life-threatening heart rhythms. Investigators expect a detectable difference between the impedance of normal and infarcted myocardium (approximately 50 ohms).
Background: Treatments for structural heart and valve disease are quickly changing. But treatment could be improved. Researchers want to gather data from people with this disease. They want to find problems and seek new ways to make treatments better. Objective: To find people with structural heart and valve disease with common features to study. To find flaws and patterns in procedures related to this disease. To share findings with other researchers. Eligibility: People ages 18 and older who are receiving care from the structural heart and valve program at the participating NHLBI structural heart disease network sites that are part of the study Design: Participants will be screened with their consent. This will occur when they give their standard consent for medical care. Participants will have their data collected in the course of standard medical care. Data include: Demographic data Protected health data Personally identifiable data Medical records Medical images. These could include X-rays, CT scans, and MRI scans. The study could find something that would impact participants care. If this is the case, their doctors will be told. Participants data may be shared with other researchers. ...
The purpose of this observational registry is to report real-world safety and performance of VeriSight for ultrasound guided ICE imaging in percutaneous cardiac intervention procedures when used in standard clinical practice.