44 Clinical Trials for Various Conditions
Aerosol Generating Medical Procedures (AGMP) are procedures that have the potential to create tiny particles suspended in the air. These particles can contain germs such as viruses. The Coronavirus Disease 2019 (COVID-19) pandemic was caused by the novel severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). Patients infected with SARS-CoV-2 experience unusually high rates of critical illness that needs advanced airway management and intensive care unit admission. Bag-valve-mask (BVM) ventilation, endotracheal Intubation (ETI) and chest compressions are sometimes required for critically ill COVID-19 patients, and may contribute to a high risk of infection amongst Health Care Workers (HCW). To lessen HCW risk during high-risk procedures, a device called an aerosol box has been developed to place over the head of the patient, shielding the provider's face from virus droplets suspended in the air. The purpose of this research study is to better understand how particles disperse during AGMPs, more specifically during the provision of cardiopulmonary resuscitation (CPR). The project team hopes what is learned from the project can help inform infection control measures. This could help make changes to the clinical environment and make it safer for HCW's. The investigators intend to explore how an aerosol box performs in reducing contamination of HCW's who perform critical airway interventions during resuscitation events.
The objective is to evaluate the effectiveness of a Just in Time (JiT) video as compared to the AHA Heartsaver® Course and no training (control) in ability to correctly perform CPR. The secondary objective is to assess skill retention 3-9 months after the AHA Heartsaver course with and without JiT Video use. The goal of this work is to study the effectiveness of this new JiT video to improve objective knowledge- and performance-based measures of effective OHCA response, as well as subjective ratings of preparedness and likeliness to respond, compared to the standard AHA Heartsaver® CPR AED Training course.
Patients who are having problems breathing sometimes require placement of a breathing tube in their mouth and windpipe. The purpose of this breathing tube is to save the patient's life. It is common to give the patient a medication to sedate him or her before the breathing tube is placed. For patients who are gravely ill two medications are commonly used: etomidate or ketamine. Both medications have risks and benefits. Researchers at UT-Southwestern Medical Center and Parkland Memorial Hospital would like to do a study to figure out which one is better for our patients.
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.
Cardiac arrest has a very poor prognosis, especially with prolonged efforts at resuscitation, and unfortunately, survivors are often severely neurologically impaired. CPA in children is often the result of a prolonged illness rather than a sudden, primary cardiac event as is frequent in adults. This necessitates that resuscitation research must be conducted separately for pediatric and adult patients. Authorities currently endorse the use of epinephrine for restoring spontaneous circulation based on its ability to maintain diastolic blood pressure and subsequent blood flow to the heart during resuscitation. However, human studies have shown no clear survival benefit of epinephrine and have elucidated concerning adverse effects. Recently, both the European Resuscitation Council and the American Heart Association have recognized the use of vasopressin as a promising vasoconstrictor and an alternative or adjunct to epinephrine in the resuscitation of adults. Vasopressin causes profound vasoconstriction without the adverse effects of epinephrine and is associated with improved blood flow to the heart and brain. This increased cerebral blood flow has been associated with better neurologic outcome in animal studies. In light of compelling animal and human studies of combined vasopressin and epinephrine, pediatric trials are indicated for vasopressin usage in pediatric CPR. This study will evaluate the addition of the administration of vasopressin to standard advanced CPR therapy (epinephrine alone) for pediatric patients that experience in-intensive care unit CPA to assess for improved time to return of spontaneous circulation (ROSC), survival to 24 hours, survival to hospital discharge, and neurologic outcome. When a patient experiences a CPA, standard Pediatric Advanced Life Saving (PALS) protocols as endorsed by the American Heart Association will be initiated. This will include receiving epinephrine as the first vasopressor medication. Patients will then be randomized to receive vasopressin (treatment group) or epinephrine (control group) as the second vasopressor medication, if needed. If more then two doses of vasopressor medication is required in either group, epinephrine will be administered according to the PALS algorithm until the end of the event. All CPA events meeting inclusion criteria will be entered into the National Registry of Cardiopulmonary Resuscitation (NRCPR) Database, which tracts all CPA events at Children's Medical Center Dallas. Prior to commencement of the RCT, a pilot trial of 10 patients will be completed to assess preliminary safety, feasibility, and effectiveness of combination epinephrine-vasopressin for pediatric in-intensive care unit CPA refractory to initial epinephrine dosing. All pilot patients will receive vasopressin as the second vasopressor medication.
In the United States, the current standard of prehospital (i.e. outside of hospitals) emergency care for children with life-threatening illnesses in the community includes remote physician support for paramedics providing life-saving therapy while transporting the child to the hospital. Most prehospital emergency medical services (EMS) agencies use radio-based (audio only) communication between paramedics and physicians to augment this care. However, this communication strategy is inherently limited as the remote physician cannot visualize the patient for accurate assessment and to direct treatment. The purpose of this pilot randomized controlled trial (RCT) is to evaluate whether use of a 2-way audiovisual connection with a pediatric emergency medicine expert (intervention = "telemedical support") will improve the quality of care provided by paramedics to infant simulator mannequins with life threatening illness (respiratory failure). Paramedics receiving real-time telemedical support by a pediatric expert may provide better care due to decreased cognitive burden, critical action checking, protocol verification, and error correction. Because real pediatric life-threatening illnesses are rare, high stakes events and involve a vulnerable population (children), this RCT will test the effect of the intervention on paramedic performance in simulated cases of pediatric medical emergencies. The two specific aims for this research are: * Aim 1: To test the intervention efficacy by determining if there is a measurable difference in the frequency of serious safety events between study groups * Aim 2: To compare two safety event detection methods, medical record review, and video review
The NEURESCUE device is the first intelligent catheter for aortic balloon occlusion, an emergency technique that supercharges blood flow to the heart and brain within one minute from deployment. The catheter-based device is delivered via the femoral artery, temporarily inflating a soft balloon in the descending aorta to redirect blood flow towards the upper body. The objective of this study is to investigate the feasibility of the NEURESCUE device as an adjunct to Advanced Cardiac Life Support (ACLS) in adults with cardiac arrest.
This study evaluates the impact of video communication via telemedicine on the quality of emergency care provided to children by paramedic teams supported by a remote physician in a simulated out-of-hospital setting. Half of the paramedic teams will use a video telemedicine platform for communication with a physician, while the other half will use an audio-only platform.
To determine if survival to hospital discharge with good neurological outcome for adults ages 18-75 who are resuscitated from out-of-hospital VT/VF cardiac arrest without clinical signs of a heart attack do better by going straight to the cardiac catheterization laboratory or admitted to the intensive care unit for evaluation. The investigators think a large portion of resuscitated patients presenting with VT/VF have ischemic heart disease which is the cause for the arrest. And prompt access to the cardiac catheterization laboratory to reverse the blocked artery will improve survival with good neurological outcomes.
In the U.S. alone, over 300,000 people per year have sudden out-of-hospital cardiac arrest (OHCA), and less than 1 out of 10 survive. The current standard practice for treating OHCA is to perform cardiopulmonary resuscitation (CPR) and Advanced Cardiovascular Life Support (ACLS) at the scene until either the heart is restarted or resuscitation efforts are considered hopeless and discontinued. An alternative strategy for those with refractory OHCA is expedited transport with ongoing mechanical CPR to an Emergency Department capable of performing extracorporeal cardiopulmonary resuscitation (ECPR). The purpose of study is to test if this strategy is feasible and beneficial.
This is a prospective, observational, multi-center cohort study of pediatric cardiac arrests. The purpose of the study is to determine the association between chest compression mechanics (rate, depth, flow fraction, compression release) and patient outcomes. In addition, the investigators will determine the association of post cardiac arrest care with patient outcomes.
The investigators hypothesized that pre-arrival instructions would increase the likelihood of bystanders performing Cardiopulmonary Resuscitation (CPR).
The goal is to develop a two-tiered monitoring system to improve the care of patients at risk for clinical deterioration on general hospital wards (GHWs) at Barnes-Jewish Hospital (BJH). The investigators hypothesize that the use of an automated early warning system (EWS) that identifies patients at risk of clinical deterioration, with notification of nurses on the GHWs when patients are identified, will reduce the risk of ICU transfer or death within 24 hrs of an alert. As a substudy, the investigators will pilot the use of a wireless pulse oximeter to establish feasibility and to develop algorithms for a real-time event detection system (RDS) in these high-risk patients.
Cardiac arrest is a sudden, unexpected loss of heart function. Therapeutic hypothermia, in which the body's temperature is lowered and maintained several degrees below normal for a period of time, has been used to successfully treat adults who have experienced cardiac arrest. This study will evaluate the efficacy of therapeutic hypothermia at increasing survival rates and reducing the risk of brain injury in infants and children who experience a cardiac arrest while in the hospital.
Cardiac arrest is a sudden, unexpected loss of heart function. Therapeutic hypothermia, in which the body's temperature is lowered and maintained several degrees below normal for a period of time, has been used to successfully treat adults who have experienced cardiac arrest. This study will evaluate the efficacy of therapeutic hypothermia at increasing survival rates and reducing the risk of brain injury in infants and children who experience a cardiac arrest while out of the hospital.
Our project aims to improve the delivery and assessment of cardiopulmonary resuscitation (CPR) during pediatric cardiac arrest by introducing 2 novel approaches: 1. We will evaluate the effectiveness of a novel, credit card sized, and highly affordable "nano-card" CPR visual feedback device to improve compliance with HSFC CPR guidelines when used during simulated pediatric cardiac arrest; 2. We will also develop and study a novel, "Just-in-Time" (JIT) CPR training video, integrating proven educational methods (video-based lecture, expert modeling, practice-while-watching), and use the CPR visual feedback device to provide real-time coaching. We hypothesize that: H1: The use of a CPR visual feedback device will improve compliance with current HSFC CPR and resuscitation guidelines during a simulated pediatric in-hospital cardiac arrest scenario compared with standard CPR with no visual feedback. H2: A JIT CPR Training Video, viewed by healthcare providers 2-4 weeks prior to the resuscitation event, will improve compliance with current HSFC CPR and resuscitation guidelines during simulated pediatric cardiac arrest compared with those healthcare providers with no prior exposure to the JIT CPR Training Video. H3: That there is poor correlation between providers' perception of CPR quality and actual measured CPR quality H4: That task load varies depending on provider role and type of clinical scenario
The design of this protocol is a prospective observational study to objectively measure the rate, depth and quality of chest compressions and ventilations delivered during cardiac arrest in the Pediatric Intensive Care Unit (PICU) and Emergency Department (ED) settings utilizing the MRx/Q-CPR. The data collected will be analyzed for several purposes - for comparison with current American Heart Association (AHA) Cardiopulmonary Resuscitation (CPR) guidelines and to determine chest wall stiffness for CPR modeling efforts and construction of biofidelic manikins or test dummies for CPR and auto safety.
The goal of this pragmatic prospective Type 1 Hybrid Implementation-Effectiveness Trial study is to learn if The Situation Awareness Incorporating Multidisciplinary Teams Reduce Arrests In (SAMURAI) the PICU Bundle can reduce PICU CPR events. The SAMURAI PICU Bundle includes an automated PICU warning tool, twice daily huddles and mitigation plans. The main questions it aims to answer are: Is the adapted bundle will be acceptable, feasible, and appropriate to stakeholders prior to implementation? Will there be at least a 30% relative reduction in PICU CPR events following successful implementation of the bundle? Each site will: Adapt and implement SAMURAI PICU Bundle which includes an automated PICU warning tool, twice daily huddles and mitigation plans
RACE-CARS is a real-world cluster-randomized trial designed to evaluate a multifaceted community and health systems intervention aimed to improve outcomes of out-of-hospital cardiac arrest. RACE-CARS will enroll 50 counties in North Carolina that are estimated to have a total of approximately 20,000 patients with cardiac arrest over a 4-year intervention period. County "clusters" will be randomized in a 1:1 ratio to intervention versus usual care. The trial duration is 7 years, which includes a 6-month start-up (including recruitment and randomization) period, a 12-month intervention training phase, a 4-year intervention period, a 12-month follow-up for to assess quality of life in survivors of OHCA, and a 6-month close-out and data analysis period.
Effective chest compressions are essential to survival in an arrest patient receiving CPR (cardiopulmonary resuscitation). A challenge in providing effective chest compressions is frequent interruption of compressions. A major cause of a recurrent interruption of chest compressions is pulse checks. Pulse checks are difficult to quickly and accurately perform in the AHA recommended time interval of under 10 seconds for reasons ranging from inexperience to body habitus. Unnecessarily long pulse checks often delay reinitiating chest compressions leading to a fall in perfusion pressure to the coronary arteries lowering the chances of return of spontaneous circulation (ROSC). To potentially solve the issues of evaluating the chest compression effectiveness and minimize the time interval of pulse checks, the authors have constructed a novel device that can be rapidly applied to an arresting patient and evaluate the current state of the circulatory system. The device is called the Rapid Pulse Confirmation (RPC) device. It is designed to applied over a major artery (radial, ulnar, brachial, carotid, and femoral) and detect Doppler shift of red blood cells to gauge red blood cell velocity and rate of pulsation. Feasibility testing on the device was carried out using patients requiring cardiopulmonary bypass. Arrest and return of spontaneous circulation during cardiopulmonary bypass is predictable and provided an ideal environment to test the initial performance of a device meant to detect return of spontaneous circulation. The primary working hypothesis was that there would be no significant difference in time of detection of ROSC between the arterial line catheter and the RPC device at the end of cardiopulmonary bypass. The secondary hypothesis was that there would be no difference in pulse rate reading between the arterial line catheter and the RPC device.
Patients presenting following out of hospital cardiac arrest will undergo bedside ultrasound as per the hospital clinical practice. Initial 6 months include recording of current state of practice and timing of pauses and timing of ultrasounds. The second 6 months will follow an educational intervention to teach "pre-imaging". This is the technique of imaging the heart during cardiopulmonary resuscitation (CPR) to find the heart and center it on the ultrasound screen before CPR is stopped. The goal is to decrease CPR pause times when ultrasound is performed post out of hospital (OOH) cardiac arrest.
This is a Phase II, single center (Under the Center for Resuscitation Medicine at the University of Minnesota Medical School), partially blinded, prospective, intention to treat, safety and efficacy clinical trial, randomizing adult patients (18-75 years old) with refractory ventricular fibrillation/pulseless ventricular tachycardia (VF/VT) out-of hospital cardiac arrest (OHCA) who are transferred by emergency medical services (EMS) with ongoing mechanical cardiopulmonary resuscitation (CPR) or who are resuscitated to receive one of the 2 local standards of care practiced in our community: 1) Early Extracorporeal Membrane Oxygenation (ECMO) Facilitated Resuscitation or 2) Standard Advanced Cardiac Life Support (ACLS) Resuscitation
Hypothermia on admission to the intensive care unit (ICU) following cardiopulmonary bypass (CPB) is common. The investigators propose that rewarming hypothermic (≤ 35 C) patients admitted to the intensive care unit following procedures using CPB with heated humidified breathing circuits (HHBC) in addition to conventional forced air warming blankets will shorten time to normothermia. Secondarily it may shorten time to extubation, improve coagulopathy, and metabolic derangements seen with hypothermia.
The main objective of this study is to evaluate the efficacy of intravenous sodium nitrite compared with placebo in reducing the occurrence of CSA-AK as diagnosed by KDIGO criteria during the first 72 hrs after cardiac surgery in high-risk patients undergoing cardiac surgery. Secondary objectives are to determine whether IV sodium nitrite achieves adequate pharmacokinetics (PK) in patients undergoing cardiac surgery with the use of CPB.
There is significant data showing that the quality of CPR performed is quite poor. Recent studies have shown that when real-time visual corrective feedback is available to CPR providers, quality (compression depth and rate) improves. Pilot work at John's Hopkins Children's Hospital indicates that providing a CPR Coach whose role it is to provide real-time coaching during cardiac arrest, further improves the quality of CPR. This study will assess the impact of a CPR Coach for improving CPR quality and CPR perception in a team of healthcare providers during simulated CPA.
Cardiac Arrest is among the leading causes of death, with survival still well under 50% and the majority of the survivors suffering from moderate to severe neurologic deficits. The human, social and economic costs are staggering. During resuscitation, damage is mitigated if chest compressions and other medical care are optimal, allowing some blood to reach the brain and some oxygen to reach the cells. Once the heart starts beating again, which is called return of spontaneous circulation, brain perfusion is reestablished, but usually not to normal. The now damaged brain is very fragile, can be sensitive to any changes in blood pressure or metabolic abnormalities, and swelling might set in. Hypoperfusion can persist, without the clinician's knowledge. All of these events further damage the brain and diminish the odds that the patient will regain a normal life. Therefore, the hours following return to spontaneous circulation are critical to the patient's future recovery, and constitute a window of opportunity to maximize the brain ability to heal. In order to optimize resuscitative efforts and post-arrest management, clinicians must know what is actually happening with the most vital organ, the brain. The problem is that it is very difficult to do in a comatose patient. The available technologies only reveal indirect evidence of brain suffering, like the swelling on CT-scans, but not to continuously evaluate at the bedside if the brain actually receives enough blood. The FDA recently approved a device named the c-flow, made by ORNIM. This device looks at red blood cells in the brain and the speed at which they move to evaluate an index of cerebral perfusion. It does so with sensors put on the patient's forehead, which emit and detect ultrasounds and infrared light. This index can inform the clinician about the amount of blood flow the brain receives, and it can be put in place very quickly, even during resuscitative efforts, and without any danger for the patient. The study looks at how well the information obtained with the c-flow matches the one obtained from other indirect indices and, more importantly, how well it predicts patient outcome. The investigators wish to establish threshold values of this index of perfusion that predict a good recovery so that this information may be used to optimize patient's neurological outcome in the near future.
Non-convulsive seizures (NCS) following cardiac arrest are common and are associated with worse neurologic outcomes and increased mortality. More prolonged seizures (status epilepticus) are associated with worse outcomes. Earlier diagnosis and treatment of seizures may lead to earlier termination of seizures and decreased seizure burden. This study will evaluate whether bedside intensive care unit (ICU) provider interpretation of a type of EEG called DSA EEG can be used by non-neurologists to diagnosis seizures more rapidly than continuous EEG's routinely read by neurologists.
The primary objective of the trial is to determine if survival to hospital discharge is improved with early therapeutic administration of a new Captisol-Enabled formulation of IV amiodarone (Nexterone-PM101) compared to placebo.
More than 300,000 Americans experience out-of-hospital cardiac arrest annually, with overall survival rates averaging less than 5%. Low survival rates persist, in part, because manual chest compressions and ventilation, termed standard cardiopulmonary resuscitation (S-CPR), is an inherently inefficient process, providing less than 25% of normal blood flow to the heart and the brain. Hemodynamics are often compromised further by poor S-CPR techniques, especially inadequate chest compression and incomplete chest recoil. Active Compression Decompression CPR (ACD-CPR) is performed with a hand-held device that is attached to the patient's chest, and also includes a handle containing a metronome and force gauge to guide proper compression rate, depth and complete chest wall recoil. The impedance threshold device (ITD) is designed for rapid connection to an airway adjunct (e.g. facemask or endotracheal tube) and allows for positive pressure ventilation, while also impeding passive inspiratory gas exchange during chest wall decompression. Prior studies have shown that the combination of ACD-CPR + ITD enhances refilling of the heart after each compression by augmenting negative intrathoracic pressure during the decompression phase of CPR, resulting in improved cardiac and cerebral perfusion. The intrathoracic pressure regulator (ITPR) is a next generation inspiratory impedance therapy. The ITPR uses a regulated external vacuum source to lower the negative intrathoracic pressure and is therefore less dependent on the quality of CPR (e.g., completeness of chest wall recoil). The ITPR generates a pre-set continuous and controlled expiratory phase negative intrathoracic pressure that is interrupted only when positive pressure ventilation is needed to maintain oxygenation and provide gas exchange. The purpose of the study is to compare the early safety and hemodynamic effects of S-CPR, ACD- CPR + ITD, and S-CPR + ITPR in patients with out-of-hospital cardiac arrest.
Each year in the United States, 300,000 people suffer from a Cardiac Arrest (CA), and of them, there is a 90% mortality rate. Out-of-Hospital arrests, in particular, have a 1-5% survival to hospital discharge. High quality CPR is crucial to lowering the mortality rate and increasing survival, yet only 15-30% of out-of-hospital CA victims receive bystander CPR. Studies have shown that prompt administration of CPR dramatically improves outcomes. In a recent study from Switzerland, lay bystander CPR doubled the survival rate at one month. Our study will look to train family members of at-risk cardiac patients in the skills of CPR through the American Heart Association's (AHA) CPR Anytime Friends and Family Personal Learning Program (CPR Anytime) to see if these family members are able to learn and perform quality CPR in the event that their family member should suffer a cardiac arrest.