Active clinical trials for "Heart Arrest"

Cardiac arrest is the most common cause of death in the United States and as many as 590,000 Americans suffering a cardiac arrest each year. Despite advances in care, as many as 50 to 89% of patients who are resuscitated after a cardiac arrest die in the hospital. Brain injury is the most common cause of death and disability after cardiac arrest. The investigators use advanced brain monitoring in patients who are at high risk of death after cardiac arrest, with the goal of preventing ongoing brain injury. The most common problem the investigators have observed is low oxygen levels in the brain, which is often very difficult to treat. In this study, the investigators plan to use two additional brain monitors in the care of these high risk patients: a monitor for seizures and a monitor of the amount of blood flow in the brain. The investigators will use these to detect and treat potential causes of low brain oxygen levels. The main hypotheses are that electrical events in the brain such as seizures and "spreading depolarizations" will occur during times of low brain tissue oxygen level, and that treating these events and low blood flow will reduce the rate of low brain oxygen levels.

The investigators aimed to investigate the effect of delayed hospitalization on the basis of the call time on the clinical outcomes of patients with OHCA patients using a nationwide OHCA registry.

Following successful cardiopulmonary resuscitation (CPR) after out of hospital cardiac arrest (OHCA), 50% of patients admitted to the Intensive Care Unit (ICU) die. As most patients die due to brain damage sustained during cardiac arrest and the subsequent reperfusion phase, effective neuroprotective strategies could potentially improve outcome. In animal experiments, 2-Iminobiotin (2-IB), a selective neuronal and inducible nitric oxide synthase (NOS) inhibitor, given upon reperfusion has been shown to improve memory function. Since 2-IB has not shown any safety issues in preclinical and clinical studies. Before embarking on large studies with efficacy as primary endpoint, safety, tolerability and pharmacokinetics need to be established. Objective: Evaluate short term safety and tolerability, and the pharmacokinetic properties of 2-IB in adult patients after OHCA. Study design: Phase 2, single-centre, open-label, dose-escalation intervention study. Study population: Three cohorts of eight evaluable patients admitted to the ICU after OHCA due to a cardiac cause. Intervention: The first eight patients will receive 0,055 mg/kg 2-IB every 4 hours intravenously, 6 times in total (part A). The second eight patients (cohort B) will receive 0,165 mg/kg every 4h iv, 6 times in total. The third eight patients (cohort C) will receive 0,5 mg/kg every 4h iv, 6 times in total. Medication has to be given as soon as possible and within 6h after OHCA. Escalation to the next dose level will only be done after pharmacokinetic analyses have performed, no relevant safety issues have been encountered, and the DSMB approves to move to the next dose level. Main study parameters/endpoints: Study parameters to evaluate short term safety and tolerability will be vital signs (heart frequency, blood pressure, cardiac ischemia) before and until 15 minutes after administration. (Serious) Adverse Events will be recorded on the ICU (up to 7 days) or until discharge from the ICU. For evaluation of the pharmacokinetics profile of 2-IB, 9 plasma samples will be analysed. Secondary parameters: Biochemical markers Neuron specific Enolase and s100b at 24h and 48h after start of study drug, occurrence of SAEs until 30 days after OHCA including death, long term term efficacy as determined by the Cerebral Performance Category (CPC), the Informant Questionnaire on Cognitive Decline in the Elderly (IQCODE) or the Telephone Interview Cognitive Status (TICS) scale at 30 days after OHCA.

The PERSEUS protocol is a new approach to the resuscitation of highly monitored patients with cardiac arrest. It aims at the optimization of all the available physiological parameters and the full exploitation of both the "cardiac pump" and "thoracic pump'. This protocol will help to titrate chest compressions, ventilation, and vasopressor dosing to physiological parameters, increasing survival after cardiac arrest with favorable neurological outcome

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.

The general aim of this study is to compare the efficacy and safety of tenecteplase to standard treatment during cardiopulmonary resuscitation in patients suffering from out-of-hospital 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

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.

This is a pilot randomized controlled trial (RCT) to gain preliminary evidence regarding the acceptability, tolerability, safety, and efficacy of a combined intervention of Stellate Ganglion Blockade (SGB) and psychoeducation on trauma symptoms and health behaviors in patients exhibiting early PTSD symptoms after cardiac arrest (CA). Primary Aim 1 (Feasibility outcomes): Gain preliminary evidence regarding the acceptability, tolerability, and safety of conducting a randomized trial that evaluates a single SGB treatment in conjunction with psychoeducation among CA patients with early PTSD symptoms. Secondary Aim 1 (Treatment-related outcomes): Test, whether SGB/psychoeducation treatment in CA patients with clinically significant PTSD symptoms is associated with reduced cardiac anxiety, PTSD symptoms, and improved health behaviors (physical activity and sleep duration), assessed objectively by a wrist-worn accelerometer for 4 weeks post-discharge.

The purpose of this observational study is to assess the effectiveness of Curodont Repair Fluoride Plus (CRFP) compared to other tooth-specific treatments (silver diamine fluoride (SDF), sealants, or other FDA-approved treatments) in preventing progression to cavitation in patients with at least one early non-cavitated dental caries lesion. The study will also evaluate the effectiveness of CRFP in comparison to no tooth-specific treatment control groups, including whole mouth treatments such as: 2.26% fluoride varnish, 1.23% fluoride foam, and 5000 ppm fluoride prescription toothpaste; and no treatment, on caries arrest and in preventing progression to cavitation in patients with at least one early non-cavitated dental lesion.