View clinical trials related to Cardiac Arrest.
Filter by:Blood samples are collected and stored in a biobank for later analysis of circulating substances in peripheral blood and genetic variations in patients with severe critical illness and risk of death. The aim is to analyze stored samples in order to identify substances that can help predict the outcome of critically ill patients, but also to optimize treatment and possibly prevent serious illness and death in the future.
It's crucial to determine whether a pulse is present or not in patient with cardiac arrest. But more and more studies have shown that manual palpation is unreliable for detecting pulse 1-4. Failure to detect pulselessness may cause delay of chest compression and directly affect the patient's outcome. Likewise, failure to rapidly detect return of spontaneous circulation may cause prolonged chest compression and increase associated injury during resuscitation. More and more studies have demonstrated that echo guided pulse detection is feasible 5-7. The aim of our study is to check carotid pulse via ultrasound. This is a prospective study and the patient selection is in-hospital or out of hospital cardiac arrest. A curvilinear ultrasonography transducer is used and placed transversely on either right/left carotid artery under pulsed-wave doppler mode to check whether the pulse is present or not. The result of ultrasonography will be compared with manual palpation and to determine the accuracy and effectiveness of clinical usage.
Sudden cardiac death is one of the main causes of morbidity and mortality worldwide. Cardiac arrest requires prompt intervention by cardiopulmonary resuscitation (CPR). The resuscitation guidelines are the current recommendations for CPR and are revised by expert panels such as the "European Resuscitation Council (ERC)". Up to now, a parameter for assessing the quality of CPR is missing and further monitoring methods are urgently needed. Near-infrared spectroscopy (NIRS) is a portable method for measuring regional oxygen levels in the brain. Recent clinical trials suggest that cerebral oxygenation measured by NIRS may correlate with survival and outcome after cardiac arrest. The investigators propose that NIRS technology may not only be suitable to determine or predict the outcome of the patients, but could also be a useful tool to guide the CPR providers to optimize the CPR techniques and guide the individual treatments/interventions. The present study was therefore designed to determine if NIRS guided CPR with the aim to optimize NIRS values is superior compared to the current standard practice according to published CPR guidelines (return of spontaneous circulation [ROSC] rate, short and long-term cerebral performance).
Cardiac arrest is the number one cause of death in Canada. It is often the first symptom of cardiac disease for the victims. Eighty-five percent of victims collapse in their own home. Fifty percent collapse in the presence of a family member. Bystander cardiopulmonary resuscitation (CPR) can improve the chance to survive a cardiac arrest by three to four times, but needs to be started quickly. In most communities, less than 30% of victims receive CPR before the ambulance arrives. Currently, only 8% of cardiac arrest victims can leave the hospital alive. Many things have been tried to improve the number of times people do CPR. So far, the only thing that really increased the number of times that someone did CPR is when 9-1-1 attendants started to give CPR instructions to callers over the phone. The only problem is that about 25% of cardiac arrest victims gasp for air in the first few minutes. This can fool the 9-1-1 callers and attendants into thinking that the victim is still alive. The investigators have looked at all the studies on how to help 9-1-1 attendants to recognize abnormal breathing over the phone. The investigators have also learned what should be taught after finishing a large survey with 9-1-1 attendants from across Canada. This survey was done with the help of psychologists and other education experts. It measured the impact of attitudes, social pressures, and 9-1-1 attendants' perceived control over their ability to recognize abnormal breathing and cardiac arrest. Then the investigators developed a teaching tool which helped Ottawa 9-1-1 attendants recognize abnormal breathing. When they could do that, they could also recognize more cardiac arrest. The main goal of this project is to use the tool developed in Ottawa in more centres to help 9-1-1 attendants save the lives of even more cardiac arrest victims across Canada.
The aim of the study is to determine prognostic value of plasma mitochondrial DNA and cytochrome C after cardiac arrest. The study will be conducted in three parts: 1. Determine plasma concentrations of mitochondrial DNA and cytochrome C in healthy population. 2. Determine release profile of mitochondrial DNA and cytochrome C to plasma after cardiac arrest. 3. Determine plasma prognostic value of mitochondrial DNA and cytochrome C after cardiac arrest and compare it with established prognostic methods.
Define the frequency and survival pattern of cardiac arrests in relation to the hospital day of event and etiology of arrest.
Serum uric acid level is a commonly measured biomarker. The association between serum uric acid level and the risk of developing cardiovascular diseases has been observed in some studies, while others showed controversial results. Estimation of this association may help to predict cardiovascular outcomes and may guide new treatment strategies. The hypothesis is that increased serum uric acid level is associated with a range of cardiovascular diseases.
The purposes of the study are to 1) study alterations in the metabolomic profile of patients exposed to post-ischemic conditions and 2) study alterations in myocardial infarction size of patients exposed to post-ischemic conditioning.
The aim of this study is to evaluate the prognostic value of the suppression ratio monitored by Bispectral Index for prediction of neurologic outcome after cardiac arrest. All patient admitted to our intensive care unit after a cardiac arrest are included. The results of the suppression ratio will be collected in the 6 first hours of admission. We will evaluate the link between suppression ratio and cerebral performance category score collected at three months.
In this study, we want to find out whether the recognition of cardiac arrest using a smart watch is feasible or not. If this idea is possible, the recognition of cardiac arrest using the smart watch is easy and fast to the witness, like a general person. By using the smart watch, the emergency response system for cardiac arrest and the bystander CPR or BLS is beginning earlier than using conventional cardiac arrest recognition method in field.