View clinical trials related to Hemorrhagic Shock.
Filter by:Early detection of ongoing hemorrhage (OH) before onset of hemorrhagic shock is a universally acknowledged great unmet need, and particularly important after traumatic injury. Delays in the detection of OH are associated with a "failure to rescue" and a dramatic deterioration in prognosis once the onset of clinically frank shock has occurred. An early alert to the presence of OH would save countless lives. This is a single site study, enrolling 48 patients undergoing liver resection in a "no significant risk" prospective clinical trial to: 1) further identify a minimal subset of noninvasive measurement technologies necessary for the desired diagnostic performance, 2) validate the performance of our Phase I algorithm, and 3) re-train the algorithm to a Phase II human iteration. The main outcome variables are non-invasive measurements that will be used for machine learning, not real-time patient management. The data generated will be used later for discovery and validation in traditional and innovative machine learning.
Despite advances in trauma resuscitation, a paucity of therapeutic interventions are available early enough to reduce the downstream morbidity and mortality attributable to hemorrhage, shock and coagulopathy. Due to the time sensitive nature of the treatment of hemorrhage, the ideal resuscitation intervention would entail use of a blood product containing all essential hemostatic components, closest to time of injury, where prevention or reversal of the devastating downstream consequences of shock and coagulopathy can occur. This proposal will characterized the efficacy of whole blood resuscitation initiated in the prehospital setting to patients in hemorrhagic shock which represents this ideal intervention post-injury. These results will have great potential to dramatically change the way trauma resuscitation occurs today.
Bleeding is the most avoidable cause of death in trauma patients. Up to one-third of severely injured trauma patients are found to be coagulopathic and forty percent of the mortality following severe injury is due to uncontrollable hemorrhage in the setting of coagulopathy. It has been established that early administration of fresh frozen plasma decreases mortality following severe injury, replacing lost coagulation factors, improving the coagulopathy and restoring blood volume. This study will determine if giving plasma to severely injured trauma patients during ambulance transport versus after arrival to the hospital will help reduce hemorrhage, thus decreasing both total blood product administration and mortality.
This project seeks to determine the effect of prehospital resuscitation with hypertonic saline vs. conventional crystalloids on the inflammatory response after injury. The leading cause of late mortality following injury is multiple organ dysfunction syndrome (MODS), which results from a dysfunctional inflammatory response after injury. Previous studies suggest that hypertonic saline may be beneficial by modulating this initial response and decreasing subsequent organ injury. This project takes advantage of a unique opportunity, afforded by an NIH-funded multi-center clinical trial of hypertonic resuscitation (conducted by the Resuscitation Outcomes Consortium), to obtain blood samples from patients enrolled in this trial to analyze inflammatory responses early after hypertonic vs. conventional resuscitation. This study was an ancillary study to the main randomized clinical trial and thus prospective observational in nature The proposed study will be carried out in experiments grouped in three Specific Aims: Aim 1 provides a thorough investigation of the immunomodulatory response following hypertonic resuscitation with regard to neutrophil, monocyte, and T cell responses at serial time points after injury and resuscitation. Aim 2 comprises experiments to investigate the mechanisms by which hypertonicity may alter inflammatory cell signaling. Aim 3 seeks to correlate the laboratory findings with clinical endpoints reflective of immune dysfunction including inflammation, organ failure, nosocomial infection, and sepsis. The investigators hypothesize that hypertonic resuscitation will be associated with modulation of the excessive inflammatory response seen after injury and thus will result in reduced rates of inflammatory organ injury.
It is anticipated that the use of tissue oxygen monitoring to measure brain tissue oxygen and deltoid muscle oxygen will provide more precise information about focal brain ischemia and systemic hypoperfusion than current techniques and measures such as blood pressure, heart rate and intracranial pressure. Understanding the relationship between tissue oxygen tension collected from the brain and deltoid muscle in critically injured patients could lead to a broader understanding of the important metabolic and cellular events that occur following severe injury and the changes induced by therapeutic interventions. Furthermore, the use of interventions designed to improve tissue hypoxia, as measured by low brain or muscle tissue oxygen, may improve mortality or neurological recovery after systemic trauma or head trauma compared to current approaches that do not involve tissue metabolic monitoring.