View clinical trials related to Heart Arrest.
Filter by:In the Paris (France) Medical Emergency system, in the early phase of Out-of-hospital Cardiac Arrest (OHCA), the treatment of a Ventricular Fibrillation (VF) consists of delivering an External Electric Shock (EES) by a rescuer with the use of an Automated External Defibrillator (AED). This latter realizes a cardiac rhythm analysis every two minutes. This analysis requires that chest compressions (CC) be interrupted for a while. However, CC interruptions are potentially harmful due to the brain, and heart perfusions decrease. On the other hand, the recurrence of VF occurs mostly during the first minute after the shock, whereas the delay between 2 rhythm analysis is 2 minutes. The consequence is excessive time spent in VF, which is deleterious in terms of coronary and cerebral perfusion. The investigator implements a new AED algorithm whose operating principle is as follows. One minute after an EES administration, the AED realizes a cardiac rhythm analysis during which the rescuers do not need to interrupt the chest compressions (CC): this is called the rhythm analysis " in presence of CC" The detection of a VF " in presence of CC " needs to be confirmed, " in absence of CC " The CC's are therefore interrupted for new rhythm analysis. Once the presence of VF is approved, the AED proposes a shock to be administred The aim of the study Study Design: This is a prospective observational study. The eligibility criteria are as follows: - Patients in Out-Of-Hospital Cardiac Arrest. - Basic Life support care with an AED. The primary endpoint is the " chest-compression fraction (CCF) " that represents the CPR-time performance during the ten first minutes of BLS care ( or < 10 min in case of Return Of Spontaneus Circulation (ROSC))
It is very important to ensure the tube placement in patients with cardiac arrest and unrecognized misplacement of endo-tracheal tube can lead to morbidity and mortality. In recent pandemic situations such as COVID-19 (Coronavirus disease-19), the number of cases of cardiopulmonary resuscitation with personal protective equipment (PPE) have increased. In those cases, existing methods such as auscultation and chest uprising have to be limited. Quantitative waveform capnography is recommended as the gold standard for confirming correct endotracheal tube placement in the 2010 American HeartAssociation (AHA) Guidelines for Cardiopulmonary resuscitation (CPR) and Emergency Cardiovascular Care (ECC), but it has some well-known limitations in cardiac arrest patients. Ultrasonography is a non-invasive, real-time diagnostic tool commonly used during resuscitation. Especially, tracheal ultrasonography can be performed in real-time when the tube is passed through the trachea or esophagus. Previous prospective studies revealed that tracheal ultrasonography could feasibly and rapidly confirm tracheal intubation during emergency intubation. There have already been several studies comparing the accuracy of tracheal ultrasound and capnography, but there was no study comparing the two tools under the constraints of PPE that is essential in pandemic situations as in this study. This study aimed to determine the accuracy of tracheal ultrasonography in assessing endotracheal tube position during CPR with PPE.
The most frequent access site for veno-arterial extracorporeal membrane oxygenation (VA-ECMO) is the common femoral artery (CFA), using either an open or percutaneous technique. Currently, percutaneous closure devices for femoral arterial access sites are approved for use only when a 10-F or smaller sheath has been used. However, the availability of the Perclose ProGlide (Abbott Laboratories, Chicago, IL) device has now made it possible to perform percutaneous vessel closure after using larger sheaths.The preclose technique using Perclose ProGlide, has been widely used in endovascular procedures. In a prospective randomized study, complication rates at the access site were similar in patients who underwent total percutaneous access (including percutaneous arteriotomy closure) than in those who underwent surgical cutdown and subsequent surgical closure. Total percutaneous closure of femoral arterial access sites increases patient comfort and decreases the rate of wound infections and lymphatic fistulas.[6,7] Furthermore, patients are mobilized and discharged earlier following the use of closure devices than with compression alone. Despite the above observations, no data have been published regarding percutaneous closure of femoral artery access sites in patients who have undergone VA-ECMO. In this study, we evaluated the safety and feasibility of a percutaneous closure technique using Perclose ProGlide to close the CFA access site after VA-ECMO.
This study was aimed to investigate the clinical characteristics, management and prognosis of patients developing intraoperative cardiac arrest during transcatheter aortic valve implantation
: An intrahospital CA data recording protocol has been designed following the Utstein model. Database is hosted according to European legislation regarding patient data protection. It is drafted in English and Spanish. Invitation to participate has been sent to Spanish, European and Latinamerican hospitals. Variables included, asses hospital characteristics, the resuscitation team, patient's demographics and background, CPR, post-resuscitation care, mortality, survival and long-term evolution. Survival at hospital discharge will be evaluated as a primary outcome and survival with good neurological status as a secondary outcome, analyzing the different factors involved in them
Current studies have shown that hospitalized ICU patients have a high risk of IHCA, with an incidence of about 0.6-7.8%. Early prediction of the occurrence of IHCA in severe patients can provide early intervention, prevent the deterioration of the disease, and reduce the incidence of IHCA. Therefore, researchers wanted to verify the efficacy of MEWS, NEWS, and CART scores in predicting IHCA in ICU inpatients, and to establish an early-warning scoring model that could effectively predict the risk of IHCA occurrence in ICU inpatients during hospitalization.
Differential diagnosis: ultrasound, blood gas analyse combined with examination of the patient and environment is used during Out Of Hospital Cardiac Arrest (OHCA) to screen possible underlying cause of cardiac arrest. Helicopter Emergency Medical Service (HEMS) in Helsinki has unraveled a protocol for performing differential diagnosis during OHCA. Our study aim is to test the feasibility of this protocol. Our study is a prospective medical record based study. The anesthesiologist operating in the HEMS unit fills a form after encounter of OHCA. Questioners focus on how long did execution of the protocol take, and the cause if the protocol was not completed.
The AutoPulse Resuscitation System Model 100 (ZOLL Medical Corporation, Chelmsford, MA, US) ZOLL has been used as a standard treatment for a number of subjects in this trial and granted CE marking for Europe in November of 2003. The AutoPulse device is an automated, portable, battery-powered, load-band-distributing (LDB), chest compression device, which provides chest compressions as an adjunct to performing manual cardiopulmonary resuscitation (CPR). Use of the device is intended to provide consistent chest compressions without interruption to a victim of out-of-hospital cardiac arrest (OOHCA), to reduce the impact of rescuer fatigue due to application of manual CPR, and to enable rescuers to address additional patient needs. In the present study investigators will compare electronic data generated during cardiopulmonary resuscitation stored in the different multimonitores between LDB and manual chest compressions.
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.
Over the last decades, research in cardiopulmonary resuscitation was primarily focused on uninterrupted chest compressions to restore sufficient circulation. Ventilation during ongoing chest compressions was regarded as potentially deleterious and thus not given any major scientific focus. Current guidelines advise that ventilation be monitored by end-tidal CO2 and emphasize that hyperventilation be avoided. Recent findings from arterial blood gas analyses showed high levels of arterial pCO2, resulting in a frequent occurrence of hypercapnic acidosis, which may be caused by iatrogenic hypoventilation. Ventilation during ongoing chest compressions can be hard to achieve, as nearly every breath may be terminated by simultaneous chest compressions. In case of bag ventilation the applied tidal volumes have not yet been measured und mechanical ventilators so far were not able to ventilate during chest compressions, because pressure limit settings induced termination of inspiration. The aim of this study is to provide patients with the best possible ventilation, even under ongoing chest compressions. Patients are ventilated with a new turbine-driven ventilator (Monnal T60, Air Liquide, France), which can deliver adequate tidal volumes within a very short inspiratory phase due to the inspiratory flow of > 200l/min. Thus, in deviation from the current recommendations, the ventilation rate can be doubled to 20/min, so that inspiration coincides with cardiac massage less often. The study compares effective ventilation volumes applied by two regimes, 10 breaths/min and 20/min.