Prehospital Hypertonic Saline Administration After Severe Traumatic Brain Injury.

A 25-year old male paient was critically injuried in a high speed motor vehicle collision over an hour from the nearest trauma center. Paramedics diagnosed the patient with a traumatic brain injury and increasing intracranial pressure and transported the patient to a predesignated landing zone for helicopter intercept. During transport paramedics initiated a severe traumatic brain injury protocol which included the adminisration of 3% hypertonic saline. The flight crew continued 3% hypertonic saline managment which was later transferred to the receiving trauma team. Upon trauma center arrival the patient was diagnosed with a skull fracture and subdural hematoma. The patient was transitioned to a 3% hypertonic saline infusion for the next 24 h. The need for integrating systems of care is particularly important when managing patients with severe traumatic brain injury. This case report describes a patient with a severe TBI who received prehospital 3% hypertonic saline based on an integrated protocol developed between multiple prehosptial systems and a tertiary care trauma center. Severe traumatic brain injuries (TBIs) are a potentially catastrophic event, and morbidity can rise precipitously without early interventions to prevent hypoxia and hypotension and control for rising intracranial pressure. In recent years, hypertonic saline (HTS) has shown efficacy in lowering intracranial pressures for patients experiencing TBIs, the leading cause of death and disability among children and young adults in the United States.1 Integrating care between health care providers across the acute care continuum, from prehospital systems to discharge, is paramount in providing the best patient outcomes possible, especially in health care system expansions such as air medical transport. The need for integrating systems of care is particularly important when managing patients with severe TBI. Statewide prehospital care protocols vary greatly; 78% provide ventilation guidance, 77.3% have targeted end-tidal carbon dioxide levels below < 35 mm Hg, and only 1 (of 38 reviewed) includes HTS (3%).2 One barrier to consistency in protocol development is the available literature. One trial demonstrated that a prehospital bolus of 7.5% HTS in severe TBI did not improve mortality.3 However, the Brain Foundation guidelines continue to recommend the prehospital use of hyperosmolar therapy for patients with severe TBI and evidence of impending herniation.4 Hyperosmolar therapy is also recommended as an inpatient strategy for lowering increased intracranial pressure (ICP).4 One reason for this apparent disconnect is because the ideal timing of HTS administration and its concentration have not been determined.4 A meta-analysis previously determined no one prehospital fluid is superior to another in improving the outcomes of patients with severe TBI.5 However, none of the reviewed research investigated the continued use of HTS across an integrated system of care. This case report describes a patient with a severe TBI who received 3% HTS initiated in the prehospital setting with the infusion continued upon arrival at the trauma center using a system-wide integrated protocol.

Patient Care Alterations After Point-of-Care Laboratory Testing During Critical Care Transport.

OBJECTIVE: Point-of-care laboratory testing (POCT) is associated with a reduced time to testing results and critical decision making within emergency departments. POCT is an essential clinical assessment tool because laboratory data are used to support timely critical decisions regarding acute medical conditions onditions ; however, there is currently limited research to support the use of POCT in the critical care transport environment. Few studies have evaluated the changes in patient care that occur after POCT during critical care transport. This study aims to contribute to the limited data available correlating prehospital POCT and changes in patient care. METHODS: After institutional review board approval, a retrospective review of patients transported by a critical care transport team between October 1, 2013 and September 31, 2015 was completed. During the study period, 11,454 patients were transported, and 632 (5.51%) received POCT testing. RESULTS: Patient care changes were noted in 244 (38.6%) patient tests. The most frequent patient care alterations were ventilator settings (10.9%), electrolyte changes (10.4%), and unit bed upgrades (7.1%). POCT most frequently altered care for patients with post-cardiac arrest syndrome (64.7%), sepsis/septic shock (61.8%), diabetic ketoacidosis (54.5%), or pneumonia (49.3%). CONCLUSION: Patient care alterations occurred in 38.6% of patients undergoing POCT. Patient care was most frequently changed when patients were diagnosed with post-arrest, sepsis/septic shock, diabetic ketoacidosis, and pneumonia.