View clinical trials related to Cardiac Arrest.
Filter by:Cardiac arrest ist associated with a very poor prognosis. Even though resuscitation algorithms and postcardiac arrest care have been improved there is an urgent need for measures leading to a higher survival rate. Emergency cardiopulmonary bypass (ECPB - artificial heart and lung outside the patients body) is a method which has shown good results in case reports and animal studies for cardiac arrest care. The study will be performed as comparison between the new treatment option of ECPB versus the standard of care treatment. Aim of our study is to determine the feasibility of ECPB installed in an emergency department to improve the rate of patients restoration of spontaneous circulation.
There is a correlation between hospital mortality and changes in markers of tissue perfusion, lactate, and venous oxygen saturation and carbon dioxide gradient.
Extracorporeal membrane oxygenation (ECMO) support has been suggested to improve the survival rate in patients with refractory cardiac arrest (CA). Recent studies have also highlighted the potential early application of this method in improving the prognosis of prolonged cardiac arrest both for in hospital CA (INHCA) and out of hospital CA (OHCA). The rationale for use of ECMO in these patients is to optimize early perfusion of vital organs, curing the cause of CA and waiting for the recovery of the injured myocardium. The investigators have created a flow-chart to decide which patients are eligible. The aims of this study are to evaluate if, with this flow-chart, the investigators are able to detect which patients have more probability of survival.
Sudden out-of-hospital cardiac arrest (OHCA) is a leading cause of death in Australia. The most common cause of OHCA is a heart attack. The current treatment of OHCA is resuscitation by ambulance paramedics involving CPR, electrical shocks to the heart, and injections of adrenaline. In more than 50% of cases, paramedics are unable to start the heart and the patient is declared dead at the scene. Patients with OHCA who do not respond to paramedic resuscitation are not routinely transported to hospital because it is hazardous for paramedics to undertake rapid transport whilst administering chest compressions and there is currently no additional therapy available at the hospital that would assist in starting the heart. However, a number of recent developments suggest that there may be a new approach to the resuscitation of this group of patients who would otherwise die. Firstly, Ambulance Victoria have recently introduced portable battery powered machines that allow chest compressions to be safely and effectively delivered during emergency ambulance transport. Second, The Alfred ICU will shortly be implementing a new protocol whereby the patient in cardiac arrest can immediately be placed on a heart-lung machine. This is known as extra-corporeal membrane oxygenation (ECMO). Third, the brain can now be much better protected against damage due to lack of blood flow using therapeutic hypothermia which is the controlled lowering of body temperature from 37°C to 33°C. Clinical trials have demonstrated that this significantly decreases brain damage after OHCA. Finally, The Alfred Cardiology service has an emergency service for reopening the blocked artery of the heart in patients who present with a sudden blockage of the heart arteries. This is currently not used in patients without a heart beat because of the technical difficulty of undertaking this procedure with chest compressions being undertaken. This study proposes for the first time to implement all the above interventions when patients have failed standard resuscitation after OHCA. When standard resuscitation has proved futile, the patient will be transported to The Alfred with the mechanical chest compression device, cooled to 33°C, placed on ECMO, and then transported to the interventional cardiac catheter laboratory. The patient will then receive therapeutic hypothermia for 24 hours. Subsequent management will follow the standard treatment guidelines of The Alfred Intensive Care Unit.
Sudden cardiac arrest (SCA) remains one of the major leading causes of death. Cognitive deficits are common in survivors of SCA. Postresuscitative mild induced hypothermia (MIH) lowers mortality and reduces neurologic damage after cardiac arrest. The investigators evaluated the long term neurological outcome after mild hypothermia after restoration of spontaneous circulation.
Out of hospital cardiac arrest is a major health problem. Prognosis is still poor even after return to spontaneous circulation. The pathophysiology of cardiac arrest implies ischemia-reperfusion and sepsis like syndrome. These phenomenons can lead to microvascular dysfunction explaining probably multi-organ failure after cardiac arrest. Few means allow the exploration of microvascular function in human. Muscle StO2 is a technique allowing the assessment of microvascular function non-invasively. The aim of this study is to evaluate muscle StO2 as a prognostic factor after out of hospital cardiac arrest.
The purpose of the study is to collect EEG's as close to the cardiac arrest as possible using a standard hospital EEG machine and an investigational EEG device to help determine the neurological status of the cardiac arrest patient and to help decide on possible treatment and chance of recovery. The investigational EEG machine will be simple to operate as well as easy to interpret for the clinician and the nurses. It is not to replace the electrophysiologist interpretation but to determine ealy on if further evaluation and treatment can help the patient.
Survivors of a cardiac arrest frequently develop severe postanoxic encephalopathy. Derangements in cerebral blood after return of spontaneous circulation play an important role in the pathogenesis of postanoxic encephalopathy. In the present study we examine the effect of mild therapeutic hypothermia on cerebral blood flow and carbondioxide reactivity in patients after cardiac arrest.
This is a randomized controlled prospective study which assigned patient to receive manual CPR or automatic CPR machine use. The quality and efficacy between manual CPR and machine CPR will be evaluated.
Hypothermic resuscitation is proven to be benefit to the cardiac origin cardiac arrest patients for it improve brain recovery dramatically. However, traditional cooling devices and methods, most external cooling methods, include ice blanket, cooling helmet, or ice packing lower the body temperature slowly or inefficiently which make many emergency physicians hesitate to perform hypothermic resuscitation. To improve and promote the practice of hypothermia resuscitation, more efficient temperature control method is necessary. We conduct this clinical trial to evaluate the safety and feasibility of internal cooling catheter and temperature regulatory device, which is approved by FDA in neurologic ICU for temperature control, in the cardiac arrest patients.