41 Clinical Trials for Various Conditions
This study will measure plasma concentrations of piperacillin-tazobactam and cefazolin in pediatric patients supported with extracorporeal membrane oxygenation (ECMO) aiming to better understand the pharmacokinetics of these medications in this in vivo setting.
This study will measure plasma concentrations of dexmedetomidine, fentanyl, morphine and midazolam in pediatric patients supported with extracorporeal membrane oxygenation (ECMO) aiming to understand the pharmacokinetics of these drugs in this setting.
This is a pilot study that seeks to evaluate the feasibility and safety of using a TEG algorithm in addition to traditional laboratory tests to guide transfusion and coagulation management of ECMO patients.
The objective of the study is to predict outcomes of patients on extracorporeal membrane oxygenation (ECMO) therapy by correlating cytokines and inflammatory cell patterns to clinical outcomes using data collected in the ECMO Registry at Spectrum Health.
Extracorporeal membrane oxygenation (ECMO) is a form of heart-lung bypass used to support children who suffer heart or lung failure until whatever illness caused that failure can be treated and reversed. While on ECMO, children are at increased risk of infection, including fungal infection. Treatment for fungal infection includes not only antifungal medications but also removal of any large intravenous (IV) lines. Since ECMO requires large IV lines, proper treatment of fungal infections would be difficult if not impossible. The investigators believe that giving prophylactic antifungal medication to all children on ECMO may prevent fungal infections from developing in the first place. Fluconazole is an antifungal medication that works well against the most common fungal infections and has been shown to be safe in children. Unfortunately, the ECMO machine has the potential to significantly alter the drug levels of medications so the investigators do not know the proper dose of Fluconazole to give children on ECMO. Standard dosing of fluconazole is 12mg per kilogram of body weight given intravenously once daily. Based on preliminary data and modeling from other studies, the investigators think 25mg per kilogram given once weekly will achieve proper drug levels to prevent fungal infections. The investigators have obtained FDA approval to give this dose of fluconazole to children on ECMO who are enrolled in the study. Blood samples will be collected at specific times around the first and second fluconazole doses to describe the PK and drug extraction by the ECMO circuit.
Critically ill patients with flu may receive a drug called oseltamivir. They may also receive medical therapies to support their lung function (extracorporeal membrane oxygenation; ECMO) and kidney function (continuous venovenous hemodialysis; CVVHD). CVVHD and ECMO may remove some oseltamivir from the bloodstream. The purpose of this study is to determine how much oseltamivir gets removed by CVVHD or ECMO in critically ill patients.
The purpose of this study is to determine the safety and efficacy of citrate to provide anticoagulation of an ECMO circuit without patient anticoagulation. The standard method of providing ECMO circuit anticoagulation is the use of heparin which also anticoagulates the patient and increases the risk of patient bleeding.
Short-term and long-term consequences of severe cardiac and/or lung dysfunction can be increased use of sedation, prolonged bedrest and immobility causing severe loss of muscle mass which could be a risk for muscle weakness, osteoporosis, and lowered endurance. The goal of this study is to show how a structured rehabilitation program can exhibit better short-term and long-term outcomes on patients who are treated with extracorporeal membrane oxygenation (ECMO).
There is limited data on the respiratory system mechanics and ideal mode of ventilation for patients on veno-arterial extra-corporeal membrane oxygenation (VA ECMO) post cardiac arrest. In this observational study, the investigators will review and/or obtain laboratory, hemodynamic, respiratory system mechanical, and clinical data from patients on VA ECMO. The specific aims of this study are as follows: Aim 1: To characterize the lung ventilation strategy employed in patients on VA ECMO and its success. Aim 2: To characterize respiratory system mechanics while on ECMO using esophageal manometry and Electrical Impedance Tomography (EIT). Aim 3: To characterize right heart function and pulmonary vascular hemodynamics on the employed ventilation strategy. The overarching hypothesis is that fine-tuned individualized ventilation might be superior to an algorithm that does not account for cardiac and pulmonary functions. Therefore, the aims of this study are to identify areas in which the ventilation strategy may theoretically be suboptimal, which will guide future interventional studies investigating alternatives methods of ventilation which may reduce time on the ventilator after cardiac arrest, time in the intensive care unit, and need for veno-venous ECMO.
This single-center, open-label study will evaluate the safety and efficacy of subcutaneous heparin anticoagulation compared to the standard of care systemic intravenous anticoagulation during veno-venous extracorporeal membrane oxygenation for respiratory failure.
This study is to test the usefulness of ultrasound dilution recirculation measurements in patients receiving venovenous extracorporeal membrane oxygenation as therapy. The ultrasound dilution measurements determine the efficiency of support provided by venovenous extracorporeal membrane oxygenation. At the present time there are no other devices available to make recirculation measurements.
The primary objective is to characterize the prevalence and type of ABI following cannulation for pediatric patients who require ECMO support. The secondary objective is to describe the time course and rates of ABI using ultralow-field bedside MRI relative to both duration of ECMO support and clinical imaging obtained in routine care of pediatric ECMO patients.
The goal of this clinical trial is to compare the use of veno-arterial extracorporeal membrane oxygenation (VA ECMO) with and without left ventricular (LV) unloading in patients being treated for cardiogenic shock (CS). The main aims of the study are: 1. To determine the physiologic effects on cardiopulmonary congestion of adding LV unloading to VA ECMO 2. To determine the effects on myocardial function of adding LV unloading to ECMO 3. To test the effects on myocardial recovery of adding LV unloading to VA ECMO Participants who are being treated with VA ECMO will be randomized to receive or not receive LV unloading in the form of an intra-aortic balloon pump (IABP). Over the course of the study, the investigators will obtain measurements via lab work, echocardiography, and pulmonary artery catheter that will allow comparison of the two groups.
Acute compartment syndrome (ACS) is a surgical emergency that can develop in patients on extracorporeal membrane oxygenation (ECMO). ACS is a type of limb ischemia, which means that the limb, such as the arm or leg, loses blood flow. Patients on ECMO can develop this condition for many reasons, but most commonly from the ECMO procedure itself. This most commonly involves the leg. Key symptoms of ACS include severe pain, loss of pulses, loss of feeling, and inability to move the limb. However, because patients on ECMO are often sedated, ACS is difficult to diagnose as patients can not report symptoms. As a result, the only available tool for diagnosing ACS may be measurement of pressures in the limb. This is normally done with a needle-device, which is inserted into the leg for a single measurement. However, a recently developed device, called the MY01 Continuous Compartment Pressure Monitor, allows for continuous pressure readings instead of a single measurement. Multiple measurements may allow for much greater accuracy in diagnosing ACS, which may result in faster time to surgery and potentially save more limbs than single measurements. This device may also be less invasive than an older method of continuous pressure measuring, which uses a needle and tubing that is 14-gauge in size. Therefore, this study aims to compare 3 different types of methods for diagnosing ACS in patients on ECMO, which are 1) Standard of Care, 2) Standard of Care and MY01, and 3)Standard of Care and 14-gauge slit catheter.
Critically ill children supported by extracorporeal membrane oxygenation (ECMO) receive large volumes of prophylactic platelet transfusions to prevent bleeding. However, mounting evidence has demonstrated significant morbidity and mortality associated with these transfusions. The ECmo hemoSTAtic Transfusions In Children (ECSTATIC) pilot trial will test two different platelet transfusion strategies, based on two different platelet counts thresholds, one high (higher platelet transfusion strategy) and one low (lower platelet transfusion strategy). The pilot will gather the necessary information to perform a full trial which will provide a better understanding of how to transfuse platelets to children supported by ECMO and reduce the associated morbidity.
The goal of this pilot clinical trial is to test if ICU level ventilator protocols are appropriate interventions to study differences in ventilator strategies for patients with acute respiratory failure supported by VV-ECMO. The main questions it aims to answer are: * will clinicians closely follow different ICU ventilator protocols * will different ICU ventilator protocols change the way that patients are treated. Participants will be assigned to one of two ventilator protocols based on the month that they are first started on ECMO. Researchers will compare standard lung-protective ventilation to ultra-lung protective ventilation protocols to see how this changes how the ventilator is set for patients.
Decannulation from venovenous extracorporeal membrane oxygenation (VV-ECMO) at the earliest and safest time would be expected to improve outcomes and reduce cost. Daily assessments for readiness to liberate from therapies have demonstrated success in other realms of critical care. A recent single-center study demonstrated that a protocolized daily assessment of readiness for liberation from VV-ECMO was feasible and did not raise any major safety concerns, but the effect of this protocolized daily assessment on clinical outcomes remains unclear. Further, the manner in which ECMO is provided, weaned, and discontinued varies significantly between centers, raising persistent concerns regarding widespread adoption of protocolized daily assessment of readiness for liberation from VV-ECMO. Data from large a randomized controlled trial is needed to compare the effects of a protocolized daily assessment of readiness for liberation from VV-ECMO versus usual care on duration of ECMO support and other clinical outcomes.
A Clinical Events Committee (CEC) will include Cardiac Surgery Professor and chief of cardiac surgery Rose Kelly MD, Professor of Medicine Ganesh Raveendran MD at the University of Minnesota who is the direction of Interventional Cardiology and Professor of Medicine at the University of Minnesota David Benditt. They will review and adjudicate serious and unexpected adverse events independently from the PI and co investigators.
TITRE - Trial of Indication-based Transfusion of Red Blood Cells in ECMO, is a multicenter, prospective, randomized clinical trial. The overarching goal of TITRE is to determine whether restricting red blood cell (RBC) transfusion according to an indication-based strategy for those with bleeding and/or deficit of tissue oxygen delivery, compared with transfusion based on center-specific hemoglobin or hematocrit thresholds, can reduce organ dysfunction and improve later neurodevelopment in critically ill children receiving Extracorporeal Membrane Oxygenation (ECMO) support.
ASCEND researchers are partnering with families of children who receive extracorporeal membrane oxygenation (ECMO) after a sudden failure of breathing named pediatric acute respiratory distress syndrome (PARDS). ECMO is a life support technology that uses an artificial lung outside of the body to do the lung's work. ASCEND has two objectives. The first objective is to learn more about children's abilities and quality of life among ECMO-supported children in the year after they leave the pediatric intensive care unit. The second objective is to compare short and long-term patient outcomes in two groups of children: one group managed with a mechanical ventilation protocol that reserves the use of extracorporeal membrane oxygenation (ECMO) until protocol failure to another group supported on ECMO per usual care.
Moderate intensity titrated dose anticoagulation has been used in patients receiving extracorporeal membrane oxygenation (ECMO) to prevent thromboembolism and thrombotic mechanical complications. As technology has improved, however, the incidence of thromboembolic events has decreased, leading to re-evaluation of the risks of anticoagulation, particularly during venovenous (V-V) ECMO. Recent data suggest that bleeding complications during V-V ECMO may be more strongly associated with mortality than thromboembolic complications, and case series have suggested that V-V ECMO can be safely performed without moderate or high intensity anticoagulation. At present, there is significant variability between institutions in the approach to anticoagulation during V-V ECMO. A definitive randomized controlled trial is needed to compare the effects of a low intensity fixed dose anticoagulation (low intensity) versus moderate intensity titrated dose anticoagulation (moderate intensity) on clinical outcomes during V-V ECMO. Before such a trial can be conducted, however, additional data are needed to inform the feasibility of the future trial.
Patients in end-stage cardiac failure and/or respiratory failure may be started on a rescue therapy known as Extracorporeal Membrane Oxygenation (ECMO). One of the major clinical questions is how to manage the ventilator when patients are on ECMO therapy. Ventilator Induced Lung Injury (VILI) can result from aggressive ventilation of the lung during critical illness. VILI and lung injury such as Acute Respiratory Distress Syndrome (ARDS) can further increase the total body inflammation and stress, this is known as biotrauma. Biotrauma is one of the mechanisms that causes multi-organ failure in critically ill patients. One advantage of ECMO is the ability to greatly reduce the use of the ventilator and thus VILI by taking control of the patient's oxygenation and acid-base status. By minimizing VILI during ECMO we can reduce biotrauma and thus multi-organ failure. Since the optimal ventilator settings for ECMO patients are not known, we plan to study the impact of different ventilator settings during ECMO on patient's physiology and biomarkers of inflammation and injury.
Veno-arterial extra-corporeal membrane oxygenation (VA-ECMO) is used as a rescue strategy for patients in acute hemodynamic deterioration such as cardiogenic shock and cardiopulmonary arrest with severe pulmonary congestion. VA ECMO is the fastest way to stabilize a patient with cardiogenic shock and improve end-organ perfusion. However, one of the major disadvantages of peripheral VA-ECMO is that it provides no left ventricular unloading and increases left ventricular (LV) afterload secondary to the retrograde blood flow. Therefore, LV wall tension and myocardial oxygen demand may actually increase in the setting of VA ECMO. The Impella® device is a miniature rotary blood pump which can be inserted retrograde across the aortic valve. In this configuration, it withdraws blood from the LV and ejects it into the ascending aorta. It unloads the left ventricle, reducing LV wall tension and myocardial oxygen demand and increasing myocardial blood flow. The Impella® 5.0 is an FDA approved pump designed for intermediate support in patients with severe, cardiogenic shock. The axillary positioning allows for early extubation and ambulation and is more stable than groin placement. In present practice, the decision to place an Impella® pump in VA-ECMO patients is based on the perceived need for direct LV unloading or when a bridge device is required to transition off ECMO support. Patients with peripheral VA ECMO are managed with inotropic agents at the beginning and once patients develop pulmonary edema mechanical LV unloading is considered electively. The advantage of LV unloading with Impella® has been demonstrated in recent studies. We also reported that concomitant implantation of Impella® with VA ECMO for LV unloading resulted in improved survival and recovery of ventricular performance in patients with cardiogenic shock. Compared to delayed elective LV unloading, early LV unloading could lead to decreased pulmonary edema, improved oxygenation delivery to the myocardium, increased chance of LV recovery and improved survival. The objective of this prospective study is to assess whether the early direct ventricular unloading using axillary Impella® leads to higher rates of cardiac recovery, defined as survival free from mechanical circulatory support, heart transplantation or inotropic support at thirty days, compared with the conventional, elective placement of Impella® after developing significant pulmonary congestion.
This is an open label, randomized study comparing the clinical outcomes of unfractionated Heparin and Bivalirudin for anticoagulation in adult subjects requiring ECMO support.
This study will examine the pharmacokinetics of the various, routinely given antibiotics, sedatives, and opioids in patients undergoing venous-venous extra-corporal oxygenation (ECMO). Little is known about the distribution and effectiveness of antibiotics in this particular patient population.
Newborns and children with life-threatening heart and lung failure may require support with ECMO (extracorporeal membrane oxygenation). With ECMO, oxygen and carbon dioxide are exchanged and circulated throughout the body even if the heart is unable to do so. Unfortunately, ECMO can cause breakdown of the red blood cells (known as hemolysis). For unclear reasons, newborns are at particularly high risk of hemolysis while being supported by ECMO. The amount of hemolysis is measured with concentrations of a breakdown product from red blood cells known as free hemoglobin. One possible reason for high free hemoglobin levels in newborns on ECMO could be related to another blood protein called haptoglobin. Haptoglobin is known to help in clearing free hemoglobin through the kidneys into the urine. However, haptoglobin levels in newborns can be very low and increases slowly during the first few months of life. Free hemoglobin may be inappropriately high in newborns supported by ECMO because of low levels of haptoglobin. The purpose of this study is to characterize haptoglobin, free hemoglobin, and hemolysis in newborns and children supported by ECMO and compare those values to age-matched newborns and children not on ECMO.
The investigators will prospectively enroll 30 neonatal and pediatric ECMO patients at a single pediatric Level 1 trauma center. The patients will be randomized into two arms; one arm will receive unfractionated heparin and the other arm will receive bivalirudin. There will be 15 patients in each arm for a total of 30 patients. Primary aim will be to compare the efficacy of bivalirudin to unfractionated heparin.
This study seeks to compare outcomes of 2 different methods of cardiopulmonary support during lung transplant surgeries.
Heparin is a blood thinner used to prevent blood clots in patients on a form of life-support called ECMO. Heparin can cause bleeding - the most common complication of ECMO. New materials used in ECMO machines may help prevent clots - this could allow the use of lower doses of heparin which might reduce the risk of bleeding. Our study will compare low dose to high dose heparin in patients on ECMO. We think low dose heparin may be adequate to prevent clotting, but may cause less bleeding and be safer for patients.
The objective of the study is to determine the quality of life of patients in the years following treatment with extracorporeal membrane oxygenation (ECMO). The study population will include all adults treated with any configuration of ECMO at Duke University Medical Center during the period of Jan 1, 2009 and Dec 31, 2015. Patient's will be contacted by direct mail, in conjunction with a surgeon who performed their ECMO procedure or managed them while on ECMO, and asked to complete a validated survey (WHOQOL-Bref) which assesses quality of life. In addition, patients will be asked to opt-in to participate in a phone survey in which they can give a narrative about their ICU experience and answer specific questions regarding long-term comorbidities. Data will be stored in a secure online server which is HIPAA compliant and analyzed by the department of anesthesiology statistical support services. De-identified data will be shared with the WHO as specified in their usage agreement.