View clinical trials related to Heart Arrest.
Filter by:Single center randomized-controlled trial in out-of-hospital cardiac arrest (OHCA) patients. This study will investigate the feasibility and utility of the Resuscitative Endovascular Balloon Occlusion of the Aorta (REBOA) procedure using a REBOA catheter device in patients who have experienced an OHCA and have not regained return of spontaneous circulation (ROSC).
Cardiac arrest is a major health problem that carries a high mortality rate. Substantial research and development have been put into changing the outcome of cardiac arrest and despite the advent of automated external defibrillators (AED), increase in bystander Cardiopulmonary resuscitation (CPR) and automated CPR devices (ACPR), the proportion of patient survival to hospital discharge has only minimally improved. The objective is to investigate safety and performance of the Resuscitative Endovascular Balloon Occlusion of the Aorta (REBOA) procedure as an adjunct to Advanced Life Support (ALS) for treatment of refractory cardiac arrest.
The purpose of this study is to evaluate, in patients presenting with out-of-hospital cardiac arrest (OHCA) by ventricular fibrillation, refractory to 3 external electric shocks, the efficacy of a direct intravenous injection of 20 mmol KCl on their survival at hospital arrival.
Endpoint implementation of reactions initiated by ischemia is the mitochondrial transition pore permeability. Mitochondria pores opening results in a release of factors triggering apoptosis primarily the cytochrome С Inhibition of the pores opening protects ischemic damage of the cells. The key enzyme regulating the mitochondrial permeability transition pore is GSK-3b: the phosphorylation of the enzyme inactivates the enzyme and prevents pore opening. Aim of studi is to determine content of the phosphorylatcd GS K-3b in neurons of rat brain in the model of total tschemia/reperfusion.
With the increase in life expectancy of the general population and advances in medicine, there is now a population with a higher amount of cardiovascular diseases that lead to an increased risk of sudden cardiac arrest. In most cases, this occurs in extra-hospital settings such as family homes, shopping centres, public transport and before people without any knowledge or training in basic life support. On the other hand, for every minute that passes without adequate attention of the victim, the probability of surviving or continuing to live with neurological severe sequelae decreases by 10%. In developed countries, public policies have been created to encourage basic life support education to the general population. In Colombia, because of the high prevalence of these diseases and the need for public health strategies, a law was issued to provide access to automatic external defibrillators (AEDs) in public places. However, it has not been developed strategies for education on this subject. For that reason, the investigators created an educational strategy of self-learning, which consists of a complete basic life support course based in new Information and Communication technologies with tools to manufacture a mannequin and a homemade DEA, which will allow continuous training, with a very low cost compared to traditional life support training. The clinical trial will compare that two educational strategies, evaluating as primary aid, which approach has higher knowledge retention of life support chain at 6 months in students after the workshop. As secondary objectives, the investigators would evaluate the efficient in terms of response times, costs and student satisfaction. This study will be carried out in high school students from two different high schools, without prior training in Life support. Both strategies will be distributed randomly. The experimental group will carry out the self-learning strategy based on ICT (Information and Communication Technologies), with which they will be retrained every month, and the control group will carry out the conventional training only once as usual. Subsequently, each of the objectives will be evaluated at six months. It is proposed that the self-learning strategy is superior compared to conventional training, requiring fewer resources to perform it and allows constant retraining, which improves retention and quality in a resuscitation process.
ReTEECA Trial. Rescue TransEsophageal Echocardiography for In-Hospital Cardiac Arrest. This trial is aimed at studying the utility and interventional outcomes of rescue transesophageal echocardiography (RescueTEE) to aid in diagnosis, change in management, and outcomes during CPR by using a point of care RescueTEE protocol in the evaluation of in-hospital cardiac arrest (IHCA). This is an interventional prospective convenience sampled partially blinded phase II clinical trial with primary outcomes of survival to hospital discharge (SHD) with RescueTEE image guided ACLS versus conventional ACLS.
Rescu Epistry includes data points pertaining to prehospital and in-hospital clinical treatments and responses to therapy, survival to discharge and functional outcome data for all cases.
Hypoxic ischemic brain injury (HIBI) is the ensuing brain injury after cardiac arrest and is the primary cause of adverse outcome. HIBI is caused by low oxygen delivery to the brain. The patient's blood pressure is primary determinant of oxygen delivery to the brain. International guidelines recommend maintaining uniform blood pressure targets in all patients, however, this 'one size fits all approach' fails to account for individual baseline differences between patient's blood pressures and extent of underlying disease. Recently, 'autoregulation monitoring', a novel brain monitoring technique, has emerged as a viable tool to identify patient specific blood pressures after brain injury. This personalized medicine approach of targeting patient specific blood pressure (MAPopt) is associated with improved outcome in traumatic brain injury. It has not been evaluated in HIBI after cardiac arrest. Recently, I completed a first-in-human study demonstrating the ability to identify MAPopt in HIBI patients using neuromonitoring (microcatheters inserted into the brain tissue). The proposed study in this grant is to take the next step and investigate the changes in key brain physiologic variables (brain blood flow and oxygenation) before and after therapeutically targeting MAPopt in HIBI patients. This interventional study will serve as the basis to embark on a pilot randomized control trial of MAPopt targeted therapy versus standard of care in HIBI patients after cardiac arrest.
Single centre randomized controlled two arm clinical trial of patients after out of hospital cardiac arrest with return of spontaneous circulation. The trial objective is to investigate external cooling of cardiac arrest patients after cardiac arrest with the CAERvest cooling device. After checking inclusion and exclusion criteria and immediately after return of spontaneous circulation, the CAERvest device will be filled and placed on the supine patient's chest. A recording oesophageal temperature probe will be inserted and connected to the defibrillator. Then the patient will be transported to the Emergency Department. After admission to the emergency department, an additional endovascular cooling device will be placed and the patient will be cooled to 33°C for 24 hours (starting after reaching the target temperature range of under 34°C) with the endovascular cooling device. Then the patient will be rewarmed at 0.25 °C/h. The CAERvest device will be removed, when a temperature below 34°C is reached. After rewarming, the temperature will be controlled to be below 37.5°C for until 48 hours after cardiac arrest. After this time point pyrexia (core temperature above 37.5°C) will be treated with common pharmaceutical measures. Sedation, analgesia and relaxation will be discontinued at 36.5°C. Neurologic evaluation will be started not before 72 hours after cardiac arrest with a predefined evaluation protocol. During follow up the following secondary outcomes will be recorded: Survival to hospital discharge, survival to 30 days, survival to 6 months, best neurologic function within 30 days, best neurologic function within 6 months, and quality of life at 6 months.
A selected group of patients with refractory cardiac arrest may benefit from inhospital treatment and this may warrant transfer to the hospital with ongoing CPR. In patients with VF or ventricular tachycardia (VT) the underlying cause may be reversible and damage to other organs is limited at the time of the arrest. Many patients will have a coronary event that can be treated by angioplasty. However, up to now absence of ROSC poses a barrier for angioplasty, and most patients are therefore not even transported to a hospital. With the use of extra corporeal membrane oxygenation (ECMO) the circulation can be restored immediately, providing time to diagnose and treat the underlying cause of the cardiac arrest. International cohort studies show that a strategy of pre-hospital triage and transport to a cardiac arrest expertise center for "rapid-response" ECMO and coronary revascularization is feasible and improves survival. A clinical pathway will encompass intense cooperation and optimal logistics between several paramedical and medical disciplines, i.e. from prehospital ambulance service to intensive care. Incorporation of mechanical chest compressions devices (LUCAS™), rapid-response veno-arterial (VA-)ECMO (Cardiohelp, Maquet), and ECMO assisted revascularization in a dedicated clinical pathway will offer a potential lifesaving treatment option that is in accordance with the recommendations in the current Guidelines. The aim of the study is to investigate the feasibility of a new local clinical pathway in our hospital to provide ECPR for refractory OHCA patients.