ABSTRACT
OBJECTIVES: To assess pediatric critical care transport (CCT) teams' performance in a simulated environment and to explore the impact of team and center characteristics on performance. STUDY DESIGN: This observational, multi-center, simulation-based study enlisted a national cohort of pediatric transport centers. Teams participated in three scenarios: non-accidental abusive head injury (NAT), sepsis, and cardiac arrest. The primary outcome was teams' simulation performance score. Secondary outcomes were associations between performance, center and team characteristics. RESULTS: We recruited 78 transport teams with 196 members from 12 CCT centers. Scores on performance measures that were developed were 89% (IQR 78-100) for NAT, 63.3% (IQR 45.5-81.8) for sepsis, and 86.6% (IQR 66.6-93.3) for cardiac arrest. In multivariable analysis, overall performance was higher for teams including a respiratory therapist (RT; (0.5 points [95% CI: 0.13, 0.86]) or paramedic (0.49 points [95% CI: 0.1, 0.88]) and dedicated pediatric teams (0.37 points [95% 0.06, 0.68]). Each year increase in program age was associated with an increase of 0.04 points (95% CI: 0.02, 0.06). CONCLUSIONS: Dedicated pediatric teams, inclusion of RTs and paramedics, and center age were associated with higher simulation scores for pediatric CCT teams. These insights can guide efforts to enhance the quality of care for children during interfacility transports.
ABSTRACT
Judicious balance of fluids is needed for optimal management of acute respiratory distress syndrome (ARDS). Achieving optimal fluid balance is difficult in patients with disorders of fluid homeostasis such as diabetes insipidus (DI). There is little data on the use of Furosemide to aid in balancing fluid and electrolytes in patients with DI. Here, we present a critically ill 11-year-old female with developmental delay, septo-optic dysplasia, central DI, and respiratory failure secondary to COVID-19 ARDS. She required careful titration of a Vasopressin infusion in addition to IV Furosemide for successful management of fluid and electrolyte derangements. On admission, she demonstrated high-volume urine output with mild hypernatremia (serum sodium 156 mmol/L). Despite her maximum Vasopressin infusion rate of 8 mU/kg/hr, by day two of admission, she voided a total of 4 L resulting in severe hypernatremia (serum sodium 171 mmol/L). With continually high Vasopressin infusion rates, her overall fluid balance became increasingly net positive, although her hypernatremia persisted. Her ARDS continued to worsen. After 48 hours of the addition of intermittent Furosemide, successful diuresis along with resolution of hypernatremia was achieved. The combination of IV Furosemide with Vasopressin infusion resulted in tailored diuresis and more controlled titration of serum sodium levels than adjustment in Vasopressin and fluids alone. These results are in contradistinction to the published literature, which focuses on the use of thiazide diuretics in managing DI. This experience highlights the potential for loop diuretics to aid in establishing a desired fluid and electrolyte status in managing patients with both DI and ARDS.
ABSTRACT
The coronavirus disease 2019 (COVID-19) pandemic has required simulation-based medical education to adapt to physical distancing regulations in order to protect learners and facilitators. The "split patient" model allows for physical distancing of learners in pediatric high-fidelity simulations. This model was able to be used with the Rapid Cycle Deliberate Practice to teach pediatric residents basic and advanced life support skills and the principles of Crisis Resource Management.
ABSTRACT
BACKGROUND: Advanced Trauma Life Support resuscitation follows a strict protocolized approach to the initial trauma evaluation. Despite this structure, elements of the primary and secondary assessments can still be omitted. The aim of this study is to determine if a cognitive aid checklist reduces omissions and speeds the time to assessment completion. We additionally investigated if a displayed checklist improved performance further. METHODS: A series of 131 simulated trauma resuscitations were performed. Teams were randomized to 1 of 3 arms (no checklist, handheld checklist, or displayed). The scenarios were recorded and analyzed to determine time to completion and absolute completion of tasks of the primary and secondary survey. The workload of individual team members was assessed via NASA-TLX. RESULTS: There was no difference in time to completion of surveys among the 3 arms. In the primary survey, there was a nonsignificant increase in the number of completed tasks with the use of the displayed checklist. In the secondary survey, there was a significant improvement in task completion with the displayed checklists with improved evaluation of the pelvis (P = 0.011), lower extremities (P = 0.048), and covering the patient (P = 0.046). There was a significant improvement in performance in those reported among nurse documenters with use of the displayed checklist. CONCLUSIONS: Despite a structured approach to trauma resuscitations, omissions still occur. The use of a displayed checklist improves performance and reduces omissions without delaying assessment. Better compliance with Advanced Trauma Life Support protocols may improve patient outcomes.