View clinical trials related to Heart Defects, Congenital.
Filter by:This study is the extension of the CLARINET study [NCT00396877 -EFC5314] in neonates or infants with cyanotic congenital heart disease palliated with a systemic-to-pulmonary artery shunt. The primary objective was to assess the safety up to 18 months of age of the extended use of Clopidogrel 0.2 mg/kg/day in patients for whom the shunt was still in place at one year of age. The secondary objective was to assess the efficacy on the occurrence of shunt thrombosis requiring intervention or any death.
One known risk of pediatric heart surgery is the possibility for brain damage. This problem results from a lack of oxygen rich blood flow to the brain during surgery. In order to provide the patient's brain with blood during this operation, selective cerebral perfusion is sometimes used. This technique allows for adequate blood flow to the brain, and is monitored using special sticker sensors. The sensors are applied to the patient's forehead, and a corresponding monitor indicates oxygen levels in the front part of the brain. The goal of this study is to find out if these same stickers can be applied to the base of the skull to measure cerebral oxygenation at the back of the brain, and to determine if the back of the brain is adequately oxygenated during selective cerebral perfusion in patients undergoing complex aortic arch reconstruction.
The primary objective is to confirm the long-term functionality of implantation of the Medtronic Melody TPV at 5 years is no worse than the historical control established through literature review. The secondary objectives are to evaluate long-term functionality at 10 years and to assess safety, procedural success, and clinical utility of transcatheter implantation of the Melody TPV.
The purpose of this study is to investigate the prenatal impact of abnormal cardiac structure on neurodevelopmental outcomes in children with congenital heart disease.
Background: Children having open heart surgery to repair congenital heart defects demonstrate a large inflammatory response to the heart-lung machine and to surgery itself. In general, the more intense their inflammatory response, the more critically ill they are following surgery. These children routinely require large numbers of blood transfusions during and following surgery as part of their medical management that adds to their heightened inflammatory state. Whether additional steps to "wash" blood products and remove the substances contributing to post-transfusion inflammation will limit this response, and improve the health of children following open heart surgery, remains to be studied. Aims: To compare the inflammatory response in children having open heart surgery who receive washed versus unwashed blood transfusions. Methods: We will randomly assign children having open heart surgery to one of two groups: group 1 will receive blood transfusions per the current standard of care, group 2 will receive blood transfusions that have been washed in addition to the current standard of care. We will then use blood tests to measure the inflammatory response in children of each group. We will compare the results to determine whether washing blood transfusions decreases inflammation and post-operative complications following open heart surgery. Conclusion: We believe that washing blood transfusions given to children following open heart surgery will decrease their inflammatory response and improve their overall health.
The purpose of this study is to compare cardiac output results obtained using the thermodilution push technique with the Pulmonary Arterial Catheter (PAC) to the predicted cardiac output results obtained from the non-invasive FloWave™ 1000 device.
This study will examine genetic material obtained from blood and tissue samples of patients with congenital heart disease (CHD) and heterotaxy (an abnormality in the left-right positioning of organs in the body, also called situs inversus) to gain a better understanding of these disorders and of a lung disease called primary ciliary dyskinesia (PCD). CHD is prevalent in patients with heterotaxy. It is believed that certain forms of CHD or heterotaxy may have the same genetic origin as PCD. Individuals 2 years of age or older who have a CHD or heterotaxy or both may be eligible for this study. Participants undergo some or all of the following tests and procedures: - Blood tests, electrocardiogram (EGC) and chest x-ray. - Saliva collection: Subjects rinse their mouth with water, and then spit approximately 1.5 cc of saliva into a sterile container. - Buccal swabs: A small soft, toothbrush-like swab is rubbed on the inside lining of the cheek to collect tissue samples. - Nasal tests to measure nasal nitric oxide levels and to obtain tissue samples from the inside of the nostrils: For the nitric oxide level test, a rubber probe is inserted into one of the nostrils until it fits snugly and comfortably. The subject then takes a deep breath and then exhales all the way out through the mouth through a plastic device. During exhalation, gas measurements are recorded on a computer. To obtain tissue samples, a device is inserted in a nostril and scraped gently against the inside of the nose. - Echocardiography: This ultrasound test of the heart uses sound waves to obtain pictures of the heart. A small wand with a warm clear gel is moved around the chest to obtain the images. - Abdominal ultrasound: This ultrasound test of the heart uses sound waves to obtain pictures of the abdominal organs. A small wand with a warm clear gel is moved around the abdomen to obtain the images....
Babies having heart surgery often have problems after surgery with their blood pressure and getting enough blood to their bodies. To treat this they require medicines to keep their blood pressure high enough to get blood to their bodies. The side effects of these medicines include fast heart rates and increasing the amount of work the heart has to do. Corticosteroids are made by the body and help to use the energy in the food people eat, control the chemicals in their blood and maintain their blood pressure. Corticosteroids made by the body may be decreased in patients that have major surgery. Corticosteroids help to increase blood pressure and can decrease the amount of blood pressure medicines a patient requires. Corticosteroids have been shown to increase blood pressure in patients with bacterial infections and in very small, premature babies but have only been studied in a few babies who have had heart surgery. The way corticosteroids work is unknown but may involve decreasing the body's response to being on a heart-lung machine or give steroids not being made by the patient. Corticosteroids have been shown to be helpful in treating many diseases. The purpose of this study is to look at the effects of corticosteroids in babies who have had heart surgery and need blood pressure medicines in the intensive care unit after surgery. Our idea is that getting corticosteroids will allow us to decrease the amount of blood pressure medicines each patient needs and improve how they do after surgery. We also plan to do blood tests to help determine how the corticosteroids are working. It will be randomly determined if the subject receives corticosteroids or salt water. The subject will receive a corticosteroid or salt water once a day for five days. Their vital signs will be monitored, especially blood pressure and their need for medicines to increase their blood pressure. Blood work will also be obtained to determine their body's ability to make steroids.
Each year, there are over 400,000 cardiac surgical operations performed in the United States; of which 10,000 are performed on children. These operations are made possible by the use of the heart-lung bypass machine, also known as cardiopulmonary bypass. This machine allows for the body to be supported while the heart is repaired. While this machine has been life saving, it has risks and can lead to a variety of complications. One such complication results from the fact that the patient's blood is exposed to the foreign material of the machine, such as plastic tubing. In nearly all cases of cardiac surgery, this leads to a whole body response in the patient following the operation. This response, inflammation, is characterized by alterations in the function of the heart and lungs, fever, fluid retention, and bleeding disorders in the postoperative period. While this is usually temporary and self limiting, significant morbidity occurs in approximately 1-2% of cases where this inflammatory response is present. Additionally, children appear to be more susceptible to this response. This can lead to significant postoperative complications that are not associated with the actually surgical procedure performed on the heart. The exact cause of this response is not fully understood. However, it is important to understand the triggers, timing, and pattern of this complex inflammatory response in order to modify or arrest it. Unlike other situations associated with this type of whole-body inflammatory reaction such as trauma or overwhelming infection, cardiac surgical teams have the advantage of knowing when the trigger will occur (i.e. during the cardiac operation) and hence have the opportunity for preemptive intervention in an effort to minimize the response. One such effort is the focus of this proposal. Nitric oxide (NO) is a gas that has been used for years in the treatment of lung disease in infants. It has been life saving and safe. Recently, it has been investigated for its anti-inflammatory effects outside the lungs. We propose delivering NO to the source of the greatest inflammation in cardiac surgery, the cardiopulmonary bypass machine. It is our intention to show that in doing so; we can minimize the inflammation found in the first 24 hours following cardiac surgery in children. If we are correct, the reduction of this inflammation will result in less damage to other organs of the child's body and improved outcome following surgery.
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.