View clinical trials related to Heart Septal Defects.
Filter by:This study is designed to investigate the ability of pleth variability index (PVI) to non-invasively predict fluid responsiveness in mechanically ventilated children. Patients undergoing atrial septal defect (ASD) repair in the cardiac catheterization suite will be recruited for this study. These patients are ideal candidates because very few deviations will be made from standard clinical practice. All patients will already be under general anesthesia, mechanically ventilated, monitored with pulse oximetry, and provided with intravenous fluid to compensate for their nil per os (NPO) fluid deficit. The only deviation from clinical practice will include an abbreviated echocardiographic exam, application of the Masimo pulse oximeter, and measurement of CO via a thermodilution catheter by the interventional cardiologist.
Research Question: Performing partial turbinectomy associated with rhinoseptoplasty is responsible for an increase in quality of life related to nasal obstruction when compared to no intervention in rhinoseptoplasty inferior turbinate? - Population: patients eligible for functional rhinoseptoplasty and / or aesthetic - Intervention: surgery, turbinectomy of inferior turbinates - Comparison: the absence of intervention in inferior turbinates - Primary endpoint: Quality of life related to nasal obstruction
The purpose of this study is to determine the safety, performance and efficacy of the Hyperion™ Occluder Systems during treatment of ASD and PDA patients.
Isolated ventricular septal defect (VSD) is a well know congenital heart anomaly. If discovered in infancy or early childhood surgical intervention can be of necessity depending on the size of the defect, to assure a healthy adulthood. The long-term results of surgical closure of VSD in childhood are good and after surgery the children are considered as equally healthy and physically fit as their peers. However, there is inconsistency in data regarding follow-up on this group of patients, in relation to exercise capacity as a measure of the cardiopulmonary function. To further approach this matter the post-operative cardiac factors of these patients have to be investigated. With this study the investigators intend to examine the long-term outcome on cardiac output after heart surgery in VSD-patients. It presents an opportunity to also evaluate the correlation between cardiac output determined by gas-exchange and by MRI. The overall objectives of this study are to 1) examine whether VSD-operated patients have reduced cardiac output during exercise in comparison with matched controls, and furthermore 2) to evaluate a correlation between cardiac output measured by MRI and cardiac output determined by gas-exchange. The project is designed as a long-term follow-up and method study. A cohort of 20 children who in the 1990's underwent surgical closure of a congenital VSD will be asked to participate in this study. An equal amount of healthy young adults, will function as control group. Each participant will complete two different exercise tests, a MRI of the heart during lower body exercise on a supine ergometer bicycle, and a Supine ergometer bicycle exercise test. This data can be used for comparing cardiac output between the test groups, and furthermore it allows an evaluation of the correlation between the two methods. VSD is as described, the most common congenital heart anomaly. If not intervened with in childhood, it can cause severe heart complications later in life. It is unclear whether this intervention can cause long-term impact on patients exercise capacity, and for that reason it is of great importance that we strive for improving our knowledge of the long-term postsurgical outcome after VSD-closure.
Background: Three-dimensional echocardiographic image for atrial septal defect (ASD) is useful for evaluation of defect size and shape. The investigators suggested optimal device size using three-dimensional transesophageal echocardiographic image and our formula in previous study. Purpose: In this study, the investigators seek to predict the correct device size and confirm the accuracy of the formula that we made before device closure in ASD patients.
The objective of this study is to evaluate the effectiveness and the safety of the intracardiac septal closure device (CBO), as well as the practicability of implantation of this device using the accessories (DS for CBO).
The purpose of this Phase I study is to determine the safety of a drug called dexmedetomidine (DEX) as part of a balanced general anesthetic and sedative strategy for neonates and infants undergoing corrective cardiac surgery that requires the use of cardiopulmonary bypass for congenital cardiac problems. This study will also design and validate a dosing schema for the use of DEX as described above.
Infants with congenital heart disease and increased pulmonary blood flow have altered carnitine homeostasis that is associated with clinical outcomes; and L-carnitine treatment will attenuate these alterations and improve clinical outcomes. The investigators will pilot a trial assessing the safety and pharmacokinetics of perioperative IV L-carnitine administration in these patients. To this end, a pilot clinical trial is proposed. Infants with ventricular septal defects or atrioventricular septal defects undergoing complete surgical repair will receive L-carnitine (25, 50, or 100 mg/kg, IV) just prior to cardiopulmonary bypass (CPB) and 2hr after CPB. Carnitine levels will be measured before CPB, and before and 0.5, 1.5, 3, 5, 9, 12, and 24h after the second dose. The safety, pharmacokinetic profile, feasibility, and effect of L-carnitine administration on biochemical parameters, as well as clinical outcomes will be determined. The investigators expect this pilot to provide the data needed to proceed with a placebo-based randomized, controlled, trial.
The purpose of this study is to evaluate the sensitivity and specificity of the Cardiox Flow Detection System (FDS) in identifying an intracardiac right-to-left shunt (RLS) compared to the results of transesophageal echocardiography (TEE). RLS intracardiac shunts are associated with a number of clinically important syndromes including paradoxical thromboembolism (causing stroke or other systemic infarct), migraine headaches (particularly with aura), desaturation with obstructive sleep apnea, and decompression illness. From a research perspective, the detection of shunts in subjects with these types of syndromes is critical in helping to define the role of RLS in these disease processes. From a clinical perspective, shunt detection will be increasingly important in an era where interventional procedures for repairing cardiac defects are available for subjects determined to be at risk. The currently accepted reference standard for detection of an intra-cardiac patent foramen ovale/atrial septal defect (PFO/ASD) RLS is a transesophageal echocardiography (TEE), a procedure that is invasive, uncomfortable, and requires conscious sedation. Alternative options include transthoracic echocardiography (TTE) with injection of agitated saline (with and without Valsalva strain), a procedure that is far less sensitive than TEE due to the echocardiography imaging limitations seen in many adults. Finally, transcranial Doppler (TCD) with injection of agitated saline (with and without Valsalva strain) is a newer entrant into this arena that does not require sedation or any invasive instrumentation. The Cardiox Model 100 FDS utilizes an optical sensor positioned on the surface of the subject's skin at the scaphoid fossa of the ear. Next, a predetermined dose of an indicator dye, indocyanine green (ICG), is injected at a predetermined rate into a peripheral antecubital vein of the subject while the subject performs a breathing maneuver called a Valsalva maneuver. The exhalation by the subject into a mouthpiece connected to a pressure transducer via a flexible tubing extension, or its equivalent (ie, performing the Valsalva maneuver), is an essential step for all existing RLS detection methods. The Valsalva maneuver by the subject creates a pressure differential between the right and left sides of the heart. This Valsalva maneuver results in blood flow from the right side of the heart to the left side of the heart through an ASD, and/or causes a PFO, if present, to open, also allowing blood to flow directly from the right side to the left side of the heart without passing through the lungs (pulmonary vasculature) for oxygenation. The Earpads, including their fluorescence sensor arrays (FSA), are used to measure the relative concentration (ie, fluorescence signal level) of ICG dye in the bloodstream as a function of time. If a premature inflection or peak occurs in the ICG dye concentration level at a time point prior to the rise and fall of the concentration associated with the main bolus of indicator, then a RLS is present in the heart. The amplitude of this premature ICG dye-dilution curve (referred to as "RLS-indicator dilution curve") is used to subsequently quantify the magnitude of the right-to-left shunt by ratiometrically comparing the amplitude of this RLS indicator dilution curve to the amplitude of the main indicator dilution curve associated with that portion of the injected ICG dye that follows the normal pathway from the right side of the heart, through the lungs, and into the left side of the heart (referred to as "normal indicator dilution curve").
This project will evaluate fluid balance and oedema formation in children with the same congenital heart disease (Atrial Septal Defect) who will either go through heart surgery with the use of Cardio Pulmonary Bypass and hypothermia or through interventional catheterization. The investigators will measure interstitial colloid osmotic pressure, distribution of proteins and cytokines. The study hypothesis is that "Oedema developed during heart surgery is caused by reduced colloid osmotic pressure gradient through the capillary membrane".