63 Clinical Trials for Various Conditions
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.
This is a prospective, observational exploratory study of the performance of the Quantra System in adult patients that are undergoing an arterio-venous (AV), veno-venous (VV) ECMO or extra-corporeal life support (ECLS) procedure.
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.
Primary Research Question for the Full ULTIMATE Randomized Clinical Trial (RCT): What is the effect of ultra-protective ventilation facilitated by extracorporeal membrane oxygenation (ECMO) versus best current conventional ventilation (CV) on all-cause hospital mortality among patients with early moderate-severe acute respiratory distress syndrome (ARDS)? Secondary Research Questions: Among patients with early moderate-severe ARDS, what is the effect of ultra-protective ventilation versus CV on: (1) duration of mechanical ventilation; (2) duration of ICU and hospital stay; (3) organ dysfunction; (4) barotrauma; and (5) mortality at other time-points (ICU discharge, 28-day, 60-day)? The ULTIMATE Pilot Study: Before embarking on a definitive multinational trial to address the questions listed above, the ULTIMATE Pilot Study has these 3 specific feasibility objectives: 1. To assess adherence to our explicit mechanical ventilation protocols, with particular focus on delivered tidal volumes in both groups; 2. To estimate the rate of patient recruitment and understand barriers to recruitment; and 3. To measure and understand the reasons for crossovers or rescue by ECMO in the control group. In addition, we will monitor safety issues, recording serious adverse events in both groups.
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.
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 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.
This study is designed to provide preliminary data to determine if concentrations of piperacillin/tazobactam change in patients with severe respiratory failure receiving extracorporeal membrane oxygenation (ECMO). The investigators hypothesize that patients will have significant changes in concentration measurements, specifically an increased clearance rate and increased volume of distribution, during ECMO as compared to critically ill patients.
Veno-arterial extra-corporeal membrane oxygenation (VA-ECMO) is indicated as a haemodynamic rescue strategy in decompensated acute or chronic heart failure presenting as cardiogenic shock. It has been used across aeitologies including post-myocardial infarction, dilated cardiomyopathy, acute myocarditis and in post-cardiotomy shock. VA ECMO has a number of effects on the circulation including improved end-organ perfusion and possibly improved coronary perfusion, and is a bridge to further therapies including permanent advanced mechanical circulatory support, cardiac transplantation and to cardiac recovery. Left ventricular assist devices (LVADs) provide long-term mechanical circulatory support and also profoundly mechanically unload the left ventricle. Multiple clinical studies have documented cardiac recovery using LVAD therapy, with a rate between 10-60% in selected populations. A large body of basic science has documented the pivotal role of mechanical load in determining ventricular contractile performance across species. Therefore both clinical data and basic laboratory studies support the notion that profound ventricular unloading may result in improved cardiac performance through a variety of mechanisms ranging from triggered de novo cardiomyocyte proliferation, subcellular calcium handling reverse remodeling, changes to the extracellular matrix of the heart, reverse remodeling of the neurohormal milleu, amongst many others. One of the major deficiencies of peripheral VA-ECMO is its lack of left ventricular unloading, with associated pulmonary congestion, which can derail clinical improvement and hamper cardiac recovery. Indeed, percutaneous VA-ECMO increases LV afterload due to the retrograde blood flow, and because of the lack of venting, there may be progressive LV distension. These conditions can result in a congested, pressure-overloaded ventricle, even in the absence of echocardiographic ventricular distension. This may be ameliorated with the addition of ventricular mechanical unloading using percutaneous therapies including the percutaneous left ventricular device, Impella CP. On the platform of VA-ECMO, the addition of an Impella device to reduce ventricular loading results in improved survival and recovery of ventricular performance in the setting of cardiogenic shock. In a number of small studies, the use of additional means to unload the ventricle, principally Impella, results in cardiac recovery and less ventricular distension. In chronic heart failure, direct ventricular unloading is critical to cardiac recovery. The objective of this randomized study is to determine whether the addition of early direct ventricular unloading using Impella CP leads to higher rates of cardiac recovery, defined as survival free from mechanical circulatory support, heart transplantation or inotropic support at thirty days. This study will also examine the clinical, biochemical, echocardiographic and radiologic effects of VA ECMO with and without the addition of Impella CP to directly vent the left ventricle to address adjunct important questions such as the effects on pulmonary congestion.
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.
In a healthy patient, the lungs provide oxygen to the blood and remove carbon dioxide. However, in patients with severe lung failure, blood may not adequately be delivered to the lungs, or the lungs may not adequately supply blood with oxygen. In this case, patients may require assistance from a machine to help provide this oxygen. Extracorporeal membrane oxygenation (ECMO) is a device that acts as an artificial lung, allowing the patient to recover from their illness. Patients receiving support from ECMO are often put in a medically induced coma while their lungs heal. Certain drugs may stick to the internal surfaces of the machine; therefore leading to decreased concentrations. Patients receiving ECMO often require high doses of both pain medications and sedatives in order to provide comfort. Low doses of a drug, ketamine, may help to provide additive effects to pain relief and allow lower doses of other pain medications. The hypothesis is that patients treated with continuous intravenous ketamine, will have lower requirements of other pain medications while receiving ECMO for acute respiratory failure while achieving the desired level of sedation.
Maintenance of adequate anticoagulation or blood thinning is of critical importance when patients are placed on extracorporeal life support, such as extracorporeal membrane oxygenation (ECMO). During ECMO, a patient's entire blood volume is constantly exposed to the artificial surfaces of the ECMO circuit. This exposure activates the clotting cascade, and not only is the circuit at risk for clot formation, but the patient is also at risk for clotting within the body. Hence anticoagulation is vital in allowing the ECMO circuit to support a patient for an extended period of time. Anticoagulation on ECMO is achieved primarily by the use of a blood thinning agent called heparin. Heparin's main mechanism of action is to activate an enzyme called antithrombin III (AT III). AT III deficiency has been shown to be a common finding in pediatric patients requiring ECMO. This deficiency may then result in ineffective blood thinning by heparin. The purpose of this study is to determine how a neonate on ECMO, processes and eliminates a medication called ATryn® from their body. ATryn® is a form ATIII that is made from goat's milk. This will ultimately aid in establishing standardized dosing for the use of ATryn® in this patient population.
The purpose of this study is to assess the impact of scheduled fresh frozen plasma (FFP) administration on extracorporeal membrane oxygenation (ECMO) pump longevity in critically ill pediatric and neonatal patients. Almost all ECMO patients receive multiple FFP transfusions during their ECMO course. The investigator proposes that scheduled FFP may maintain pro and anticoagulation balance thus mitigating the need for expensive and dangerous ECMO pump changes. In addition, this may lead to less overall transfusion with all products (red blood cells, platelets, and FFP) if coagulation homeostasis is maintained. The subjects will be neonatal and pediatric patients requiring ECMO support for any reason in the pediatric and pediatric cardiac critical care units. Subjects will be randomized to receive every other day FFP infusions or FFP administration per current standard of care. ECMO pump longevity (hours) and FFP use will be compared between the two groups There is a small risk that study subjects may receive more FFP transfusions and therefore have the increased associated risks however it is also possible that these subjects may benefit from less ECMO circuit changes and/or fewer transfusions of all blood products.
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.
Infants are placed on ECMO for correction of reversible respiratory failure. Often, because a few of the reasons for respiratory failure show us similar things in the baby, it is difficult to determine exactly which is causing the biggest problem. We are now capable of measuring certain cells and proteins in these infants that may help us more accurately diagnose the exact problem. We hypothesize that infants placed on ECMO will show unique antibody-secreting cells responses and patterns of cytokine and chemokine (protein) response to illness and to the ECMO circuit. If we find unique patterns to these cells or proteins, they may be able to predict outcomes or guide treatment of these infants.
The current standard of care (SOC) for treatment of patients with acute respiratory distress syndrome (ARDS), inhalation injury, volume overload, and/or pulmonary dysfunction is mechanical ventilation (MV). However, these techniques are associated with several complications after prolonged use, including risk of infection, increased sedation requirements, pulmonary edema, ventilator-induced lung injury (VILI), barotrauma, and multi-organ failure. Extracorporeal life support (ECLS) has been used to successfully minimize, replace, or avoid the use of MV. This concept is critical as it permits ultra-lung protective MV settings, mobilization, early ambulation of patients, and timely extubation (when appropriate). Conventional ECLS typically requires blood flows of 3-6 L/min, and its cannula sizes range from 21-25 Fr. This is by definition "high-flow" as it constitutes near-complete extracorporeal circulation of patient's circulating blood volume. On the other hand, low-flow ECLS at 1-2.5 L/min has been shown to prevent deleterious shifts in pH and PaCO2 at a lower level of invasiveness, and its cannula sizes range from 19-20 Fr dual lumen cannulas (which are associated with less serial dilation). The investigators propose the use of a low-flow circuit to include the NovaLung system in conjunction with a smaller tubing set and cannula to enable earlier utilization of ECLS with less invasiveness and smaller catheters. Specifically, the study will either utilize the Crescent RA cannula (or equivalent dual-lumen cannula) or use a 15-25 Fr cannula, both with 3/8 tubing/step-down tubing, as needed, for our study. A femoral (fem)-femoral or femoral-internal jugular (IJ) approach may also be used. Carbon dioxide is six times more diffusible than oxygen across the membrane; thus, carbon dioxide transfers can occur with high efficiency at our targeted blood flows of 1-2.5L/min. Oxygen can still transfer at these blood flows, and low flow can improve oxygen levels to some degree. There are three benchtop-based manuscripts that suggest that low-flow ECMO is associated with a potential increase in factors that increase the risk of bleeding complications/circuit changes. However, the manuscripts either tested \<1 L/min blood flow rates, or the effect of cannula size was not considered. None of them included the biological component of endothelial interaction. Mitigating the risk of bleeding complications by will be completed by administering anticoagulants with a target PTT of 40-50 seconds, and by monitoring the patients and their coagulation panels closely. There may be less risk of circuit clotting in our study because of chosen flow rates (1-2.5 L/min).
The purpose of this study is to determine if transseptal extra-corporeal membrane oxygenation (ECMO) can bridge pulmonary hypertension- right heart failure (PH-RVF) patients to lung transplant safely.
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.
Extracorporeal membrane oxygenation (ECMO) is a form of cardiopulmonary life-support for critically ill patients where blood is extracted from the vascular system and circulated by a mechanical pump while it is oxygenated and reinfused into the patient's circulation. It is well known that critically ill patients may experience alterations in antibiotic pharmacokinetics, and as a result, dosing modifications are generally required. There is a need to understand how ECMO circuits affect the pharmacokinetics and disposition of drugs. This study is designed to assess the pharmacokinetics of the new broad-spectrum echinocandin, Rezafungin, in critically ill patients receiving ECMO
Adult patients on extracoporeal membrane oxygenation (ECMO) frequently experience bleeding, which is in part caused by acquired von Willebrand syndrome (vWS). Prior in vitro studies have shown that the addition of recombinant von Willebrand Factor (vWF) to ECMO patient blood samples, normalizes platelet adhesion and thrombus formation. This study is a phase I study, where adult ECMO patients with refractory bleeding will be treated with recombinant vWF a single time. The primary objectives are to evaluate the safety, tolerability, and pharmacokinetics of recombinant vWF in adult ECMO patients.
The goal of this multicenter observational clinical trial is to evaluate the safety and effectiveness of the Cardiohelp System for VA-ECMO in children with cardiac failure. The main question\[s\] it aims to answer are: * What is the safety and effectiveness of the Cardiohelp device for pediatric ECMO? * What are the optimal performance specifications of the Cardiohelp device in children? Should the Cardiohelp device be FDA-cleared for children? Children who are receiving the Cardiohelp device will be approached and consented to participate if interested. Participants will undergo a standardized data collection to estimate survival to 30 days and the prevalence of serious adverse events like stroke, bleeding, and hemolysis. Outcomes will be compared to performance goals (PG) derived from the ECMO literature. Funding Source -- FDA OOPD (Office of Orphan Products Development)
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.
Aim 1: Prospective, observational analysis of the association between echocardiographic measures of cardiac function and left ventricular unloading on VA ECMO. Aim 2: Prospective, observational analysis of the association between clinical laboratory biomarkers and left ventricular unloading on VA ECMO.
The purpose of this research study is to compare the technique of performing bilateral lung transplantation off-pump vs venoarterial ECMO (VA ECMO). The goal of the trial is to determine which technique has lower rates of primary graft dysfunction.
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.
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.
Extracorporeal membrane oxygenation (ECMO) is a form of cardiopulmonary life-support for critically ill patients where blood is extracted from the vascular system and circulated by a mechanical pump while it is oxygenated and reinfused into the patient's circulation. It is well known that critically ill patients may experience alterations in antibiotic pharmacokinetics, and as a result, dosing modifications are generally required. There is a need to understand how ECMO circuits affect the pharmacokinetics and disposition of drugs. This study is designed to assess the pharmacokinetics of the new broad-spectrum antibiotic, Cefiderocol, in critically ill patient receiving ECMO.