Use of a SimBox, a Video-Augmented, Newborn Resuscitation Simulation for Prehospital Providers to Measure Clinical Performance and Educational Experience.

OBJECTIVES: Few studies have described the current clinical practices, adherence to guidelines, and outcomes of newborn resuscitations attended by emergency medical services (EMS). SimBox, a novel, video-augmented simulation, was used to describe the adherence of prehospital providers to Neonatal Resuscitation Program guidelines, to measure satisfaction with the simulation intervention, and to describe the self-reported improvement in knowledge, skills, and attitudes after the simulation. METHODS: A prospective observational cohort study of EMS providers was designed and conducted using SimBox, an open-access simulation platform, and facilitated by EMS educators. Clinical performance measures were collected using a five-item checklist. Simulation satisfaction measures were collected through net promoter scores. Learners' demographics, and self-reported knowledge, skills, and attitudes were measured using a retrospective survey of 25 questions. RESULTS: In total, 33 facilitator and 55 learner surveys were collected across Connecticut, Colorado, and Alaska between July 2021 and September 2022. At least one deviation from clinical guidelines occurred in 22/30 (73.3%) of the sessions, with 10/30 (33.3%) teams inappropriately performing chest compressions, 5/31 (16.1%) teams not warming, drying, stimulating, and suctioning the newborn, and 7/31 (22.6%) teams not performing positive pressure ventilation correctly. Lastly, 10/30 (33.3%) teams administered an incorrect dose of dextrose-containing fluids. Very high levels of satisfaction were reported with net promoter scores of 97 and 82 out of 100 for the facilitator and learner surveys, respectively. Finally, all 55/55 (100%) of the learners strongly or somewhat agreed that the simulation improved their knowledge, teamwork, communication, and psychomotor skills. CONCLUSIONS: In this cohort of prehospital providers, clinical management decisions during a newborn resuscitation simulation often deviated from the gold-standard, newborn resuscitation guidelines. Free, online, open-access simulation resources like SimBox can be used to identify and measure practice deviations from standardized resuscitation protocols in the prehospital setting.

Pediatric Emergency Medicine Didactics and Simulation: JumpSTART Secondary Triage for Mass Casualty Incidents.

Mass casualty incidents (MCI), particularly involving pediatric patients, are high-risk, low-frequency occurrences that require exceptional emergency arrangements and advanced preparation. In the aftermath of an MCI, it is essential for medical personnel to accurately and promptly triage patients according to their acuity and urgency for care. As first responders bring patients from the field to the hospital, medical personnel are responsible for prompt secondary triage of these patients to appropriately delegate hospital resources. The JumpSTART triage algorithm (a variation of the Simple Triage and Rapid Treatment, or START, triage system) was originally designed for prehospital triage by prehospital providers but can also be used for secondary triage in the emergency department setting. This technical report describes a novel simulation-based curriculum for pediatric emergency medicine residents, fellows, and attendings involving the secondary triage of patients in the aftermath of an MCI in the emergency department. This curriculum highlights the importance of the JumpSTART triage algorithm and how to effectively implement it in the MCI setting.

Implementation of a North American pediatric emergency medicine simulation curriculum using the virtual resuscitation room.

Background: Simulation provides consistent opportunities for residents to practice high-stakes, low-frequency events such as pediatric resuscitations. To increase standardization across North American residency programs, the Emergency Medicine Resident Simulation Curriculum for Pediatrics (EM ReSCu Peds) was developed. However, access to high-quality simulation/pediatric expertise is not uniform. As the concurrent COVID-19 pandemic necessitated new virtual simulation methods, we adapted the Virtual Resus Room (VRR) to teach EM ReSCu Peds. VRR is an award-winning, low-resource, open-access distance telesimulation platform we hypothesize will be effective and scalable for teaching this curriculum. Methods: EM residents completed six VRR EM ReSCu Peds simulation cases and received immediate facilitator-led teledebriefing. Learners completed retrospective pre-post surveys after each case. Learners and facilitators completed end-of-day surveys. Primary outcomes were learning effectiveness measured by a composite of the Simulation Effectiveness in Teaching Modified (SET-M) tool and self-reported changes in learner comfort with case objectives. Secondary outcome was VRR scalability to teach EM ReSCu Peds using a composite outcome of net promoter scores (NPS), resource utilization, open-text feedback, and technical issues. Results: Learners reported significantly increased comfort with 95% (54/57) of EM ReSCu Peds-defined case objectives (91% cognitive, 9% psychomotor), with moderate (Cohen's d 0.71, 95% CI 0.67-0.76) overall effect size. SET-M responses indicated simulation effectiveness, particularly with debriefing. Ninety EM residents from three North American residency programs were taught by 59 pediatric faculty from six programs over 4 days-more than possible if simulations were conducted in person. Learners (39) and faculty (68) NPS were above software industry benchmarks (13). Minor, quickly resolved, technical issues were reported by 18% and 29% of learners and facilitators, respectively. Conclusions: Learners and facilitators report that the VRR is an effective and scalable platform to teach EM ReSCu Peds. This low-cost, accessible distance simulation intervention could increase equitable, global access to high-quality pediatric emergency education.

Severe Epistaxis in the Pediatric Patient: A Simulation for Emergency Department Management.

Severe, uncontrolled epistaxis in a pediatric patient can lead to a compromised bloody airway and the potential need for significant volume resuscitation secondary to hemorrhagic shock if not managed emergently. In this report, a simulated 11-month-old patient with underlying liver disease presents to the emergency department setting. The goal was to familiarize advanced pediatric emergency medicine trainees and experienced providers with immediate bedside interventions and clinical management steps for a patient with severe, difficult-to-control epistaxis to increase preparedness for future clinical scenarios. Additionally, this case highlights resuscitation considerations for patients with liver disease, including sources of bleeding, consulting services, medications, and approach to massive transfusion in liver disease.

Low-Cost "Telesimulation" Training Improves Real Patient Pediatric Shock Outcomes in India.

Introduction: Pediatric shock, especially septic shock, is a significant healthcare burden in low-income countries. Early recognition and management of shock in children improves patient outcome. Simulation-based education (SBE) for shock recognition and prompt management prepares interdisciplinary pediatric emergency teams in crisis management. COVID-19 pandemic restrictions on in-person simulation led us to the development of telesimulation for shock. We hypothesized that telesimulation training would improve pediatric shock recognition, process of care, and patient outcomes in both simulated and real patient settings. Materials and Methods: We conducted a prospective quasi-experimental interrupted time series cohort study over 9 months. We conducted 40 telesimulation sessions for 76 participants in teams of 3 or 4, utilizing the video telecommunication platform (Zoom©). Trained observers recorded time-critical interventions on real patients for the pediatric emergency teams composed of residents, fellows, and nurses. Data were collected on 332 pediatric patients in shock (72% of whom were in septic shock) before, during, and after the intervention. The data included the first hour time-critical intervention checklist, patient hemodynamic status at the end of the first hour, time for the resolution of shock, and team leadership skills in the emergency room. Results: There was a significant improvement in the percent completion of tasks by the pediatric emergency team in simulated scenarios (69% in scenario 1 vs. 93% in scenario 2; p < 0.001). In real patients, completion of tasks as per time-critical steps reached 100% during and after intervention compared to the pre-intervention phase (87.5%), p < 0.05. There was a significant improvement in the first hour hemodynamic parameters of shock patients: pre (71%), during (79%), and post (87%) intervention (p < 0.007 pre vs. post). Shock reversal time reduced from 24 h pre-intervention to 6 h intervention and to 4.5 h post intervention (p < 0.002). There was also a significant improvement in leadership performance assessed by modified Concise Assessment of Leader Management (CALM) instrument during the simulated (p < 0.001) and real patient care in post intervention (p < 0.05). Conclusion: Telesimulation training is feasible and improved the process of care, time-critical interventions, leadership in both simulated and real patients and resolution of shock in real patients. To the best of our knowledge, this is one of the first studies where telesimulation has shown improvement in real patient outcomes.

Pediatric Rattlesnake Envenomation: A Simulation Scenario With Optional Health Equity, Virtual Facilitation, and Senior Learner Modifications.

Rattlesnake envenomation is an uncommon but urgent cause of presentation for emergency care. Recognition of envenomation, timely administration of antivenom when indicated, and recognition of antivenom reactions are of critical importance to mitigate the local, hematologic, and systemic effects of Crotaline venom. This technical report describes the presentation and use of a simulation-based scenario of an envenomated child who requires treatment with antivenom. Optional additions to this scenario are described and include antivenom reaction, health equity considerations, and virtual facilitation.

How to Use TeleSimBox "Off the Shelf" to Connect Remote Content Experts With In-Person Simulation Participants.

In this technical report, we describe how to use TeleSimBox to run a remotely facilitated simulation to connect the facilitator with learners at a distant site. This method was developed to comply with safety measures imposed during the coronavirus disease-19 (COVID-19) pandemic to reduce the risk of viral exposure and transmission. Here, we present one example where a telesimulation naïve facilitator was trained as an in-person facilitator to enable the in-situ medical student and resident learners to participate in a pediatric emergency simulation exercise remotely guided by an off-site content expert. The case of neonatal shock was run five times during a half-day emergency department (ED) educational program with one to four participants per session. 14/15 (93%) participants completed evaluations and felt that the simulation met the case learning objectives and that connecting with the remote facilitator was useful for their learning. Feedback from the one newly trained in-person facilitator was that the tool was easy to learn how to use quickly, and the process of connecting with a remote expert was worthwhile for learners. To grab this web-based toolkit off the proverbial shelf and successfully run a telesimulation session from start to finish took approximately one hour; 20 minutes were spent in preparation the day prior and 40 minutes to set up and run the simulations the day of. We believe that this is a low-cost, efficient, and perceived to be an effective method to connect remotely located content experts and learners to engage in a simulation-based education activity when access to in-person resources and personnel is limited.

ACEP SimBox: A Pediatric Simulation-Based Training Innovation.

Thirty million pediatric visits (<18 years old) occur across 5,000 US emergency departments (EDs) each year, with most of these cases presenting to community EDs. Simulation-based training is an effective method to improve and sustain EDs' readiness to triage and stabilize critically ill infants and children, but large simulation centers are mostly concentrated at academic hospitals. The use of pediatric simulation-based training has been limited in the community ED setting due to the high cost of equipment and limited access to content experts in pediatric critical care. We designed an innovative "off-the-shelf" simulation-based training resource, "American College of Emergency Physicians (ACEP) SimBox," that provides a free low-technology manikin along with teaching aids and train-the-trainer materials to community EDs to run a simulation drill in their own workspaces with local educators. The goal was to develop an "off-the-shelf," free, open-access, simulation-based resource to improve the readiness of community EDs to triage, resuscitate, and transfer critically ill infants as measured by presimulation and postsimulation surveys measuring opinions regarding the scenario, session experience, and most valuable aspect of the session. Between January 2018 and December 2019, 179 ACEP SimBoxes were shipped across the United States, reaching 36 of 50 states. Facilitators and participants who completed the postsimulation survey evaluated the session as a valuable use of their time. All facilitator respondents reported that the low-technology manikins, paired with their institution-specific equipment, were sufficient for learning, thus reducing costs. All participant respondents reported an increased commitment to pediatric readiness for their ED after completing the simulation session. This innovation resulted in the implementation of a unique simulation-based training intervention across many community EDs in the United States. The ACEP SimBox innovation demonstrates that an easy to use and unique simulation-based training tool can be developed, distributed, and implemented across many community EDs in the United States to help improve community ED pediatric readiness.

TeleSimBox: A perceived effective alternative for experiential learning for medical student education with social distancing requirements.

INTRODUCTION: During the COVID-19 pandemic the Association of American Medical Colleges recommended that medical students not be involved with in-person patient care or teaching, necessitating alternative learning opportunities. Subsequently we developed the telesimulation education platform: TeleSimBox. We hypothesized that this remote simulation platform would be feasible and acceptable for faculty use and a perceived effective method for medical student education. METHODS: Twenty-one telesimulations were conducted with students and educators at four U.S. medical schools. Sessions were run by cofacilitator dyads with four to 10 clerkship-level students per session. Facilitators were provided training materials. User-perceived effectiveness and acceptability were evaluated via descriptive analysis of survey responses to the Modified Simulation Effectiveness Tool (SET-M), Net Promoter Score (NPS), and Likert-scale questions. RESULTS: Approximately one-quarter of students and all facilitators completed surveys. Users perceived that the sessions were effective in teaching medical knowledge and teamwork, though less effective for family communication and skills. Users perceived that the telesimulations were comparable to other distance learning and to in-person simulation. The tool was overall positively promoted. CONCLUSION: Users overall positively scored our medical student telesimulation tool on the SET-M objectives and promoted the experience to colleagues on the NPS. The next steps are to further optimize the tool.

Development and Implementation of a Pediatric Telesimulation Intervention for Nurses in Community Emergency Departments.

The need for virtual education for nursing staff has dramatically increased because of social distancing measures after the coronavirus disease pandemic. Emergency departments in particular need to educate staff on caring for patients with coronavirus disease while concurrently continuing to ensure education related to core topic areas such as pediatric assessment and stabilization. Unfortunately, many nurse educators are currently unable to provide traditional in-person education and training to their nursing staff. Our inter-professional team aimed to address this through the rapid development and implementation of an emergency nursing telesimulation curriculum. This curriculum focused on the nursing assessment and initial stabilization of a child presenting to the emergency department in status epilepticus. This article describes the rapid development and implementation of a pediatric emergency nursing telesimulation. Our objectives in this article are (1) to describe the rapid creation of this curriculum using Kern's framework, (2) to describe the implementation of a fully online simulation-based pediatric emergency training intervention for nurse learners, and (3) to report learners' satisfaction with and feedback on this intervention.

Tips for Conducting Telesimulation-Based Medical Education.

Telesimulation utilizes communications technology, such as video conferencing platforms, to provide simulation-based medical education when participants and facilitators are geographically separated. Learners interact with each other, embedded participants, and a simulated patient and/or vital sign display on the computer screen. Facilitators observe the learners in real-time and provide immediate feedback during a remote debrief. Telesimulation obviates the need to have instructors, learners, and high fidelity patient simulators (HPS) in the same place, allowing simulation-based educational sessions to occur in institutions located remotely from simulation centers or when other barriers limit in-person education and/or training. For example, due to the novel coronavirus (COVID-19) pandemic, many medical education programs temporarily discontinued in-person simulations to adhere to physical distancing guidelines. The authors have reflected upon their experiences executing telesimulation sessions since the start of the pandemic and provide these 12 tips as practical suggestions on how to successfully implement telesimulations with medical trainees. These tips are intended to guide implementation and facilitation by staff and faculty trained in simulation.

Pediatric Emergency Medicine Simulation Curriculum: Vitamin K Deficiency in the Newborn.

Introduction: The American Academy of Pediatrics recommends vitamin K prophylaxis at birth for all newborns to prevent vitamin K deficiency bleeding (VKDB). Despite a lack of evidence for serious harms, barriers to prophylaxis, including parental refusal, are rising, as are cases of VKDB. Methods: This simulation involved an infant presenting to the emergency department who decompensated due to a cerebral hemorrhage caused by VKDB and was treated by pediatric and emergency providers. The case was incorporated into the fellow and division monthly curricula, and participants completed postsimulation surveys. The patient required a secure airway, seizure management, vitamin K, and a fresh frozen plasma infusion upon suspicion of the diagnosis, plus a coordinated transfer to definitive care. The case included a description of the simulated case, learning objectives, instructor notes, an example of the ideal flow of the scenario, anticipated management mistakes, and educational materials. Results: The simulations were carried out with 48 total participants, including 40 fellows and eight attendings, from five different training institutions over 1 year. In surveys, respondents gave overall positive feedback. Ninety-four percent of participants gave the highest score on a Likert scale indicating that the simulation was relevant, and over 80% gave the highest score indicating that the experience helped them with medical management. Discussion: This simulation trained physicians how to recognize and treat a distressed infant with VKDB. The case was perceived to be an effective learning tool for both fellow and attending physicians.

Bridging the language gap for simulation resources.

With increasing use of open access platforms, simulation-based resources are being shared across geographical borders. There are benefits to designing resources with language and content which is understandable and applicable to learners in different countries. This report aims to assess the differences between scenarios from different groups and explore whether common terms can be used to make internationally relevant simulation resources in future. In collaboration between two groups producing Free Open Access Medical Education simulation resources in the UK and USA, we present observations of terms used in our simulation resources. The content within a series of simulation scenarios from both groups was reviewed, with notable differences in language collected. There are areas of overlap between the terms used in the UK and USA. Semantic, cultural and system differences were found which could prevent scenarios from being transferred between countries. The differences we describe highlight that language choice is important if simulation producers are intent on developing scenarios with international impact. There is work to be done to ensure that resources can be used internationally-embracing linguistics has the potential to aid this process, with the use of simplified language and feedback from local communities being key steps.

Wilderness Medicine (Hypothermia, Dehydration, and Ankle Injury): A Pediatric Simulation Case for Medical Trainees.

Introduction: Wilderness recreation is increasingly popular among people of all ages. Pediatric providers should have the skills to counsel on risk reduction and respond to medical emergencies in remote settings. However, few physicians receive training in wilderness medicine, and this simulation-based curriculum aims to address that gap. Methods: The scenario features an adolescent male in a remote setting with hypothermia, dehydration, and an ankle injury. The simulation is not resource intensive, utilizing a simulated patient actor and minimal equipment. The case includes a case description, learning objectives, instructor notes, example of ideal scenario flow, and anticipated management mistakes. A didactic PowerPoint highlighting the learning objectives is included. Results: The simulation was carried out over 1 year in various settings, including urban parks, the wilderness, and the classroom, with 35 medical trainees. Thirty participants (11 medical students, eight residents, and 11 fellows) completed postsimulation surveys; more than 86% gave the highest score of 5 (strongly agree) when asked if the simulation improved their understanding of managing hypothermia, dehydration, and ankle injury in the wilderness. Discussion: This simulation case trains responders to recognize an injured hiker; activate the emergency response system; initiate appropriate treatment for hypothermia, dehydration, and an ankle injury; and stabilize for transport. It reinforces medical conditions unique to the wilderness, improvisation in managing medical issues outside of the usual health care environment, and teamwork/communication skills. This case has been found to be an effective learning tool for medical students, residents, and fellow physicians alike.

Feasibility of a Low-Fidelity Pediatric Simulation-Based Continuing Education Curriculum in Rural Alaska.

Introduction Simulation-based continuing education (SBCE) is a widely used tool to improve healthcare workforce performance. Healthcare providers working in geographically remote and resource-limited settings face many challenges, including the development and application of SBCE. Here, we describe the development, trial, and evaluation of an SBCE curriculum in an Alaska Native healthcare system with the aim to understand SBCE feasibility and specific limitations. Methods The perceived feasibility and efficacy of incorporating a low-fidelity medical simulation curriculum into this Native Alaskan healthcare system was evaluated by analyzing semi-structured interviews, focus groups, and surveys over a 15-month period (August 2018 - October 2019). Subjects were identified via both convenience and purposive sampling. Included were 40 healthcare workers who participated in the simulation curriculum, three local educators who were trained in and subsequently facilitated simulations, and seven institutional leaders identified as "key informants." Data included surveys with the Likert scale and dichotomous positive or negative data, as well as a thematic analysis of the qualitative portion of participant survey responses, focus group interviews of educators, and semi-structured interviews of key informants. Based on these data, feasibility was assessed in four domains: acceptability, demand, practicality, and implementation. Results Stakeholders and participants had positive buy-in for SBCE, recognizing the potential to improve provider confidence, standardize medical care, and improve teamwork and communication, all factors identified to optimize patient safety. The strengths listed support feasibility in terms of acceptability and demand. A number of challenges in the realms of practicality and implementation were identified, including institutional buy-in, need for a program champion in a setting of staff high turnover, and practicalities of scheduling and accessing participants working in one system across a vast and remote geographic region. Participants perceived the simulations to be effective and feasible. Conclusion While simulation participants valued an SBCE program, institutional leaders and educators identified veritable obstacles to the practical implementation of a structured program. Given the inherent challenges of this setting, a traditional simulation curriculum is unlikely to be fully feasibly integrated. However, due to the overall demand and social acceptability expressed by the participants, innovative ways to deliver simulation should be developed, trialed, and evaluated in the future.

Pediatric Simulation Cases for Primary Care Providers: Asthma, Anaphylaxis, Seizure in the Office.

Introduction: Although pediatric emergencies commonly occur in the outpatient setting, studies show that primary care providers often rely on hospitals or the emergency medical system to evaluate the distressed patient. This simulation-based curriculum addresses pediatric emergencies encountered by primary care providers. The cases were facilitated by faculty at an annual conference on urgent pediatric problems. Methods: Three cases are included in this curriculum: asthma, anaphylaxis, and seizure. Each features a brief narrative description of the case, learning objectives, instructor notes, an example of the ideal flow of the scenario, and anticipated management mistakes. Also provided are tools on optimizing the simulation environment, teamwork and communication, and the debrief. Educational materials are included in the respective medical pathologies. The simulations can be run using a high- or low-fidelity mannequin. Results: The simulations were carried out annually for 4 years with over 100 providers. Participants overall felt the curriculum was relevant to their practice in the realms of medical management and patient-provider communication. Discussion: These simulation cases train primary care providers to recognize a decompensating patient, activate the emergency response system, and initiate appropriate treatment for acutely ill pediatric patients with asthma, anaphylaxis, or seizure. The cases also reinforce teamwork and communication skills with the intention of improving overall readiness in the office. The simulations have been found to be effective learning tools at the University of Washington, which continues to train outpatient providers in emergency response annually using this curriculum.

Pediatric Emergency Medicine Simulation Curriculum: Marijuana Ingestion.

Introduction: Altered mental status can be a challenging presenting symptom in children due to the wide differential diagnosis, which ranges from the relatively benign to the life threatening. Marijuana ingestion and unintentional intoxication are becoming an increasingly common cause of altered mental status in children as marijuana use and availability of enticing marijuana edibles increase in the United States. Because children present with altered mental status rather than the typical marijuana toxidrome, appropriately managing these patients in emergency settings can be particularly challenging. Methods: This simulation-based curriculum involved the evaluation and management of a 6-year-old boy who presented with altered mental status from acute marijuana intoxication unbeknownst to his parents. Participants systematically evaluated a pediatric patient with a broad differential diagnosis of altered mental status and managed the patient with acute marijuana intoxication. This scenario may be modified based on trainee level (medical student vs. resident vs. fellow). Results: A total of 20 trainees comprising six emergency medicine fellows and 14 pediatric residents and medical students participated in this simulation curriculum over three iterations. Trainees consistently rated it as an overall positive learning experience for pediatric altered mental status and toxidrome education. Discussion: Low-frequency, high-risk illnesses such as altered mental status due to marijuana intoxication require providers to be familiar with their evaluation and management. This curriculum provides instructors with the materials to successfully implement and improve the simulation over time.

Pediatric Emergency Medicine Simulation Curriculum: Submersion Injury With Hypothermia and Ventricular Fibrillation.

Introduction: Submersion injury or drowning is a leading preventable cause of pediatric mortality and morbidity. Submersion injuries are often accompanied by hypothermia and asphyxia that can lead to inadequate oxygen delivery to tissues and subsequent cardiac arrhythmias. Methods: This simulation-based curriculum involves the identification and management of a submersion injury in a 4-year-old boy who was rescued from a cold-water submersion. The simulated patient is apneic, pulseless, bradycardic, and hypothermic; he is being bag-mask ventilated on arrival without intravenous access. He ultimately develops ventricular fibrillation. Providers must recognize the degree of submersion injury, initiate early airway protection, adequately address circulation, and be alert to developing hypothermia and cardiac arrhythmias to prevent further decompensation. This scenario can be modified based on trainee level (pediatric residents vs. pediatric emergency medicine fellows). Results: A total of 22 trainees (PGY 1-PGY 6 pediatric residents and pediatric emergency medicine fellows) participated in this simulation curriculum on separate occasions and rated it as an overall positive learning experience. The curriculum's goal is to provide learners with an opportunity to manage life-threatening pediatric submersion injuries, where the correct steps need to be taken in a limited period of time. Discussion: We have provided preparatory materials to help instructors set up, run, and debrief the scenario in a standardized fashion. The debriefing tools allow for adaptation depending on learners' needs and individual experiences during the simulated scenario. Also included are supporting educational materials and a learner feedback form that can be used to evaluate the session.