Delays to Antibiotics in the Emergency Department and Risk of Mortality in Children With Sepsis.

Importance: Pediatric consensus guidelines recommend antibiotic administration within 1 hour for septic shock and within 3 hours for sepsis without shock. Limited studies exist identifying a specific time past which delays in antibiotic administration are associated with worse outcomes. Objective: To determine a time point for antibiotic administration that is associated with increased risk of mortality among pediatric patients with sepsis. Design, Setting, and Participants: This retrospective cohort study used data from 51 US children's hospitals in the Improving Pediatric Sepsis Outcomes collaborative. Participants included patients aged 29 days to less than 18 years with sepsis recognized within 1 hour of emergency department arrival, from January 1, 2017, through December 31, 2021. Piecewise regression was used to identify the inflection point for sepsis-attributable 3-day mortality, and logistic regression was used to evaluate odds of sepsis-attributable mortality after adjustment for potential confounders. Data analysis was performed from March 2022 to February 2024. Exposure: The number of minutes from emergency department arrival to antibiotic administration. Main Outcomes and Measures: The primary outcome was sepsis-attributable 3-day mortality. Sepsis-attributable 30-day mortality was a secondary outcome. Results: A total of 19 515 cases (median [IQR] age, 6 [2-12] years) were included. The median (IQR) time to antibiotic administration was 69 (47-116) minutes. The estimated time to antibiotic administration at which 3-day sepsis-attributable mortality increased was 330 minutes. Patients who received an antibiotic in less than 330 minutes (19 164 patients) had sepsis-attributable 3-day mortality of 0.5% (93 patients) and 30-day mortality of 0.9% (163 patients). Patients who received antibiotics at 330 minutes or later (351 patients) had 3-day sepsis-attributable mortality of 1.2% (4 patients), 30-day mortality of 2.0% (7 patients), and increased adjusted odds of mortality at both 3 days (odds ratio, 3.44; 95% CI, 1.20-9.93; P = .02) and 30 days (odds ratio, 3.63; 95% CI, 1.59-8.30; P = .002) compared with those who received antibiotics within 330 minutes. Conclusions and Relevance: In this cohort of pediatric patients with sepsis, 3-day and 30-day sepsis-attributable mortality increased with delays in antibiotic administration 330 minutes or longer from emergency department arrival. These findings are consistent with the literature demonstrating increased pediatric sepsis mortality associated with antibiotic administration delay. To guide the balance of appropriate resource allocation with time for adequate diagnostic evaluation, further research is needed into whether there are subpopulations, such as those with shock or bacteremia, that may benefit from earlier antibiotics.

Reducing (Behavioral) Restraint Use Through Simulation at the Bedside.

Hospitals are experiencing an influx of patients in active behavioral crises, leading to restraints as a behavior management strategy. Over 100 staff participated in simulation training designed to manage escalating patient behavior. The training had a direct impact on the reduction of restraint use and increased preparedness and confidence of participants managing escalating patient behavior. Results suggest simulation can be an effective strategy to train medical staff to manage challenging behavior and reduce restraint use.

Quality Improvement Incorporating a Feedback Loop for Accurate Medication Reconciliation.

OBJECTIVES: Medication reconciliation errors on hospital admission can lead to significant patient harm. A pediatric intermediate care unit initiated a quality improvement project and aimed to reduce errors in admission medication reconciliation by 50% in 12 months. METHODS: From August 2017 to December 2018, a multidisciplinary team conducted a quality improvement project with plan-do-study-act methodology. Continuous data collection was achieved by reviewing medications with home caregivers within 18 hours of admission to identify errors. Cycle 1 consisted of nursing training in accurate and thorough medication history documentation. Cycle 2 was aimed at improving data collection. Cycle 3 was aimed at improving pediatric housestaff processes for medication reconciliation. In cycle 4 intervention, the reconciliation process was redesigned to incorporate the bedside nurse reviewing final medication orders with the patient's home caregivers once the medication reconciliation process was complete. Intermittent maintenance data collection continued for 12 months thereafter. RESULTS: Cycle 1 and 2 interventions resulted in improvement in the medication reconciliation error rate from 9.8% to 4.7%. In cycle 2, the data collection rate improved from 61% to 80% of admissions sustained. Cycle 3 resulted in a further reduction in the medication error rate to 2.9%, which was sustained in cycle 4 and over the 12-month maintenance period. A patient's number of home medications did not correlate with the error rate. CONCLUSIONS: Reductions in admission medication reconciliation errors can be achieved with staff education on medication history and process for medication reconciliation and with process redesign that incorporates active medication order review as a closed-loop communication with home caregivers.

Dornase alpha and exhaled NO in cystic fibrosis.

Nitric oxide (NO) that is produced within the airways can be measured in the exhaled air. Concentrations of exhaled NO (FENO) are decreased in cystic fibrosis (CF) and, in cross sectional studies, have been shown to be even lower in patients with more advanced pulmonary disease. This may result from retention and metabolisation of NO within viscous airway secretions. Treatment with recombinant human DNase I (dornase alpha) modifies the rheological properties of airway secretions and thereby improves pulmonary function even in young and apparently healthy patients with CF. We studied FENO and pulmonary function in children with CF with little clinical evidence of lung morbidity in a two-year randomized double-blind placebo-controlled study with nebulized dornase alpha. Mean age at enrollment was 8 years (range 6 to 11 years), mean forced vital capacity (FVC) was 112% (range 86 to 133%), and mean forced expiratory volume in one second (FEV1)was 109% (range 88 to 128%) of predicted values. In five of six (83%) of the dornase alpha treated patients, FENO changed in parallel to changes in pulmonary function tests while no such correlation was observed in any of the eight patients receiving placebo. This difference between treatment groups was statistically significant for both FVC (P = 0.026, Wilcoxon-test) and FEV1 (P = 0.042). These data suggest that FENO may serve as a surrogate measure for evaluating the effectiveness of interventions that affect airway clearance in CF.