Human Factors Analysis of Latent Safety Threats in a Pediatric Critical Care Unit

What is the impact of simulation-based training for paediatric procedures on patient outcomes, cost and latent safety threats?

BACKGROUND

Simulation-based training (SBT) provides a safe space for medical trainees to experience realistic scenarios. SBT has been found to improve trainee performance in paediatric procedures. However, limited evidence exists regarding its effects on higher-level outcomes. This scoping review aims to identify studies that investigate the impact of SBT for procedural skills on T3 (patient outcomes) and T4 level outcomes (latent safety threats [LSTs], and hospital level costs) in paediatrics.

METHODS

Full-text articles were included if they focused on medical trainees, used simulation training for paediatric procedures and reported T3/T4 level outcomes. Six databases were searched from January 2011 to September 2022. Search strategies were developed with the assistance of a librarian. Three independent reviewers performed pilot screenings before title/abstract and full-text screenings. A data extraction sheet was created to gather information on interventions, outcomes, research design, and other study characteristics.

FINDINGS

After title/abstract screening of 4,076 sources, 50 were included for full-text review, with 15 articles selected for data extraction. Four were randomised control studies (RCTs), fourteen focused on T3 level outcomes including mortality rates, and one measured LSTs. There were no studies reporting cost-related data. Three of the studies focused on bag-and-mask ventilation, and eight mentioned the use of mannequins.

DISCUSSION

We highlight the potential effectiveness of simulation-based training of paediatric procedural skills in improving patient outcomes, such as reduced mortality rates and incidence of illness/injury.

CONCLUSION

Though the quality of research designs was low, researchers used different simulation modalities and outcome measures and showed a positive impact of SBT(e.g., decreased mortality rates).

Using In Situ Simulation to Identify Latent Safety Threats in Emergency Medicine: A Systematic Review

SUMMARY STATEMENT

This review aimed to explore existing literature on the use of in situ simulation to identify latent safety threats in emergency medicine. Studies were required to take place in a clinically active emergency department and have either a primary or secondary aim of identifying latent safety threats. A total of 2921 articles were retrieved through database searches and a total of 15 were deemed to meet the inclusion criteria.Latent safety threats were detected by a variety of methods including documentation during debrief/discussion (66%), during the simulation itself (33%), participant surveys (20%), and video analysis (20%). Using a multimodality approach with input from observers and participants from different professional backgrounds yielded the highest number of threats per simulation case (43 per case). Equipment was the most commonly reported threat (83%), followed by teamwork/communication (67%). Some studies did not report on mitigation of identified risks; formal processes should be implemented for the management of latent safety threats identified by in situ simulation. Future research should focus on translational outcomes to further strengthen the position of in situ simulation in emergency medicine.

Simulation-based operations testing in new neonatal healthcare environments

In situ simulations, those conducted in the actual clinical environment, confer a high level of contextual fidelity and have been applied to the operations testing of new healthcare environments (HCE) to identify potential threats to patient, family and staff safety. By conducting simulation-based operations testing, these latent safety threats (LSTs) - which are weaknesses in communications, human factors, system process and technologies, and the way they are linked together - can be identified and corrected prior to moving patients into the new HCE. Simulation-based operations testing has extended to the neonatal HCE, as neonatal intensive care units (NICUs) transition from open-bay to single-family room design. In this section, we define LSTs, review simulation-based operations testing in new neonatal and perinatal HCEs, review challenges associated with conducting simulation-based operations testing, and briefly review pre-construction simulation-based user-centered design of new HCEs.

Video-Recorded In Situ Simulation Before Moving to the New Combined Neonatal/Pediatric Intensive Care Facility: An Observational Study

OBJECTIVES

Moving an ICU to a new location is a challenge. The objective of this study was to use in situ simulation to identify potential problems and solutions with the new environment before commencing patient care.

DESIGN

Planned, observational video-recorded simulation study using four scenarios: delivery room management of term-neonate; delivery room management of extremely low-birth-weight infant; management and transfer of an infant with respiratory syncytial virus bronchiolitis and apnea; and management and transfer of an adolescent with septic shock.

SETTING

Academic tertiary neonatal and combined neonatal ICU/PICU.

PARTICIPANTS

Sixteen volunteers (eight physicians, eight nurses).

INTERVENTIONS

Standardized briefing introduction, with before versus after survey of thoughts about each scenario, and after 8 weeks, debriefing at least 60 minutes and additional video recording.

MEASUREMENTS AND MAIN RESULTS

A total of 91 potential problem areas were identified and included issues related to technical aspects ( n = 29), infrastructure ( n = 27), administration ( n = 19), and structure ( n = 16). Fifty-three (58%) of these potential issues could be resolved before the move, including: 15 of 29 technical, 15 of 27 infrastructure, nine of 19 administration, and 14 of 16 structural. The video analysis revealed an additional 13 problem areas (six technical, three infrastructure, two administration, and two structural). Participants felt more confident 8 weeks after the simulations (χ 2 = 12.125; p < 0.002). All 16 participants confirmed the usefulness of the in situ simulation, the majority wanted further introductions to the new ward ( n = 13) and noted a positive impact of the changes on the new ward ( n = 12).

CONCLUSIONS

In situ simulation before moving into a new facility identifies numerousness potential problem areas. Survey shows that providers feel better prepared and are more confident. Video recording reveals additional difficulties not addressed in conventional verbal debriefing.

The horizon of pediatric cardiac critical care

Pediatric Cardiac Critical Care (PCCC) is a challenging discipline where decisions require a high degree of preparation and clinical expertise. In the modern era, outcomes of neonates and children with congenital heart defects have dramatically improved, largely by transformative technologies and an expanding collection of pharmacotherapies. Exponential advances in science and technology are occurring at a breathtaking rate, and applying these advances to the PCCC patient is essential to further advancing the science and practice of the field. In this article, we identified and elaborate on seven key elements within the PCCC that will pave the way for the future.