Code Team Structure and Training in the Pediatric Resuscitation Quality International Collaborative.

OBJECTIVES: Code team structure and training for pediatric in-hospital cardiac arrest are variable. There are no data on the optimal structure of a resuscitation team. The objective of this study is to characterize the structure and training of pediatric code teams in sites participating in the Pediatric Resuscitation Quality Collaborative. METHODS: From May to July 2017, an anonymous voluntary survey was distributed to 18 sites in the international Pediatric Resuscitation Quality Collaborative. The survey content was developed by the study investigators and iteratively adapted by consensus. Descriptive statistics were calculated. RESULTS: All sites have a designated code team and hospital-wide code team activation system. Code team composition varies greatly across sites, with teams consisting of 3 to 17 members. Preassigned roles for code team members before the event occur at 78% of sites. A step stool and backboard are used during resuscitations in 89% of surveyed sites. Cardiopulmonary resuscitation (CPR) feedback is used by 72% of the sites. Of those sites that use CPR feedback, all use an audiovisual feedback device incorporated into the defibrillator and 54% use a CPR coach. Multidisciplinary and simulation-based code team training is conducted by 67% of institutions. CONCLUSIONS: Code team structure, equipment, and training vary widely in a survey of international children's hospitals. The variations in team composition, role assignments, equipment, and training described in this article will be used to facilitate future studies regarding the impact of structure and training of code teams on team performance and patient outcomes.

Closing the Gap: Optimizing Performance to Reduce Interruptions in Cardiopulmonary Resuscitation.

OBJECTIVES: The American Heart Association recommends minimizing pauses of chest compressions and defines high performance resuscitation as achieving a chest compression fraction greater than 80%. We hypothesize that interruption times are excessively long, leading to an unnecessarily large impact on chest compression fraction. DESIGN: A retrospective study using video review of a convenience sample of clinically realistic in situ simulated pulseless electrical activity cardiopulmonary arrests. SETTING: Johns Hopkins Children's Center; September 2013 to June 2017. PATIENTS: Twenty-two simulated patients. INTERVENTIONS: A framework was developed to characterize interruptions. Two new metrics were defined as follows: interruption time excess (the difference between actual and guideline-indicated allowable duration of interruption from compressions), and chest compression fraction potential (chest compression fraction with all interruption time excess excluded). MEASUREMENTS AND MAIN RESULTS: Descriptive statistics were generated for interruption-level and event-level variables. Differences between median chest compression fraction and chest compression fraction potential were assessed using Wilcoxon rank-sum test. Comparisons of interruption proportion before and after the first 5 minutes were assessed using the X test statistic. Seven-hundred sixty-six interruptions occurred over 22 events. Median event duration was 463.0 seconds (interquartile range, 397.5-557.8 s), with a mean 34.8 interruptions per event. Auscultation and intubation had the longest median interruption time excess of 13.0 and 7.5 seconds, respectively. Median chest compression fraction was 76.0% (interquartile range, 67.7-80.7 s), and median chest compression fraction potential was 83.4% (interquartile range, 80.4-87.4%). Comparing median chest compression fraction to median chest compression fraction potential found an absolute percent difference of 7.6% (chest compression fraction: 76.0% vs chest compression fraction potential: 83.4%; p < 0.001). CONCLUSIONS: This lays the groundwork for studying inefficiency during cardiopulmonary resuscitation associated with chest compression interruptions. The framework we created allows for the determination of significant avoidable interruption time. By further elucidating the nature of interruptions, we can design and implement targeted interventions to improve patient outcomes.

A National Survey on Interhospital Transport of Children in Cardiac Arrest.

OBJECTIVES: To describe the U.S. experience with interhospital transport of children in cardiac arrest undergoing cardiopulmonary resuscitation. DESIGN: Self-administered electronic survey. SETTING: Pediatric transport teams listed with the American Academy of Pediatrics Section on Transport Medicine. SUBJECTS: Leaders of U.S. pediatric transport teams. INTERVENTIONS: None. MEASUREMENTS AND MAIN RESULTS: Sixty of the 88 teams surveyed (68%) responded. Nineteen teams (32%) from 13 states transport children undergoing cardiopulmonary resuscitation between hospitals. The most common reasons for transfer of children in cardiac arrest are higher level-of-care (70%), extracorporeal life support (60%), and advanced trauma resuscitation (35%). Eligibility is typically decided on a case-by-case basis (85%) and sometimes involves a short interhospital distance (35%), or prompt institution of high-quality cardiopulmonary resuscitation (20%). Of the 19 teams that transport with ongoing cardiopulmonary resuscitation, 42% report no special staff safety features, 42% have guidelines or protocols, 37% train staff on resuscitation during transport, 11% brace with another provider, and 5% use mechanical cardiopulmonary resuscitation devices for patients less than 18 years. In the past 5 years, 18 teams report having done such cardiopulmonary resuscitation transports: 22% did greater than five transports, 44% did two to five transports, 6% did one transport, and the remaining 28% did not recall the number of transports. Seventy-eight percent recall having transported by ambulance, 44% by helicopter, and 22% by fixed-wing. Although patient outcomes were varied, eight teams (44%) reported survivors to ICU and/or hospital discharge. CONCLUSIONS: A minority of U.S. teams perform interhospital transport of children in cardiac arrest undergoing cardiopulmonary resuscitation. Eligibility criteria, transport logistics, and patient outcomes are heterogeneous. Importantly, there is a paucity of established safety protocols for the staff performing cardiopulmonary resuscitation in transport.

Cardiopulmonary Resuscitation in the Pediatric Cardiac Catheterization Laboratory: A Report From the American Heart Association's Get With the Guidelines-Resuscitation Registry.

OBJECTIVES: Hospitalized children with underlying heart disease are at high risk for cardiac arrest, particularly when they undergo invasive catheterization procedures for diagnostic and therapeutic interventions. Outcomes for children experiencing cardiac arrest in the cardiac catheterization laboratory remain under-reported with few studies reporting survival beyond the catheterization laboratory. We aim to describe survival outcomes after cardiac arrest in the cardiac catheterization laboratory while identifying risk factors associated with hospital mortality after these events. DESIGN: Retrospective observational study of data from a multicenter cardiac arrest registry from November 2005 to November 2016. Cardiac arrest in the cardiac catheterization laboratory was defined as the need for chest compressions greater than or equal to 1 minute in the cardiac catheterization laboratory. Primary outcome was survival to discharge. Variables analyzed using generalized estimating equations for association with survival included age, illness category (surgical cardiac, medical cardiac), preexisting conditions, pharmacologic interventions, and event duration. SETTING: American Heart Association's Get With the Guidelines-Resuscitation registry of in-hospital cardiac arrest. PATIENTS: Consecutive patients less than 18 years old experiencing an index (i.e., first) cardiac arrest event reported to the Get With the Guidelines-Resuscitation. INTERVENTIONS: None. MEASUREMENTS AND MAIN RESULTS: A total of 203 patients met definition of index cardiac arrest in the cardiac catheterization laboratory composed primarily of surgical and medical cardiac patients (54% and 41%, respectively). Children less than 1 year old comprised the majority of patients, 58% (117/203). Overall survival to hospital discharge was 69% (141/203). No differences in survival were observed between surgical and medical cardiac patients (p = 0.15). The majority of deaths (69%, 43/62) occurred in patients less than 1 year old. Bradycardia (with pulse) followed by pulseless electrical activity/asystole were the most common first documented rhythms observed (50% and 27%, respectively). Preexisting metabolic/electrolyte abnormalities (p = 0.02), need for vasoactive infusions (p = 0.03) prior to arrest, and use of calcium products (p = 0.005) were found to be significantly associated with lower rates of survival to discharge on multivariable regression. CONCLUSIONS: The majority of children experiencing cardiac arrest in the cardiac catheterization laboratory in this large multicenter registry analysis survived to hospital discharge, with no observable difference in outcomes between surgical and medical cardiac patients. Future investigations that focus on stratifying medical complexity in addition to procedural characteristics at the time of catheterization are needed to better identify risks for mortality after cardiac arrest in the cardiac catheterization laboratory.

A Multi-Institutional Simulation Boot Camp for Pediatric Cardiac Critical Care Nurse Practitioners.

OBJECTIVES: Assess the effect of a simulation "boot camp" on the ability of pediatric nurse practitioners to identify and treat a low cardiac output state in postoperative patients with congenital heart disease. Additionally, assess the pediatric nurse practitioners' confidence and satisfaction with simulation training. DESIGN: Prospective pre/post interventional pilot study. SETTING: University simulation center. SUBJECTS: Thirty acute care pediatric nurse practitioners from 13 academic medical centers in North America. INTERVENTIONS: We conducted an expert opinion survey to guide curriculum development. The curriculum included didactic sessions, case studies, and high-fidelity simulation, based on high-complexity cases, congenital heart disease benchmark procedures, and a mix of lesion-specific postoperative complications. To cover multiple, high-complexity cases, we implemented Rapid Cycle Deliberate Practice method of teaching for selected simulation scenarios using an expert driven checklist. MEASUREMENTS AND MAIN RESULTS: Knowledge was assessed with a pre-/posttest format (maximum score, 100%). A paired-sample t test showed a statistically significant increase in the posttest scores (mean [SD], pre test, 36.8% [14.3%] vs post test, 56.0% [15.8%]; p < 0.001). Time to recognize and treat an acute deterioration was evaluated through the use of selected high-fidelity simulation. Median time improved overall "time to task" across these scenarios. There was a significant increase in the proportion of clinically time-sensitive tasks completed within 5 minutes (pre, 60% [30/50] vs post, 86% [43/50]; p = 0.003] Confidence and satisfaction were evaluated with a validated tool ("Student Satisfaction and Self-Confidence in Learning"). Using a five-point Likert scale, the participants reported a high level of satisfaction (4.7 ± 0.30) and performance confidence (4.8 ± 0.31) with the simulation experience. CONCLUSIONS: Although simulation boot camps have been used effectively for training physicians and educating critical care providers, this was a novel approach to educating pediatric nurse practitioners from multiple academic centers. The course improved overall knowledge, and the pediatric nurse practitioners reported satisfaction and confidence in the simulation experience.

Characterization of Pediatric In-Hospital Cardiopulmonary Resuscitation Quality Metrics Across an International Resuscitation Collaborative.

OBJECTIVES: Pediatric in-hospital cardiac arrest cardiopulmonary resuscitation quality metrics have been reported in few children less than 8 years. Our objective was to characterize chest compression fraction, rate, depth, and compliance with 2015 American Heart Association guidelines across multiple pediatric hospitals. DESIGN: Retrospective observational study of data from a multicenter resuscitation quality collaborative from October 2015 to April 2017. SETTING: Twelve pediatric hospitals across United States, Canada, and Europe. PATIENTS: In-hospital cardiac arrest patients (age < 18 yr) with quantitative cardiopulmonary resuscitation data recordings. INTERVENTIONS: None. MEASUREMENTS AND MAIN RESULTS: There were 112 events yielding 2,046 evaluable 60-second epochs of cardiopulmonary resuscitation (196,669 chest compression). Event cardiopulmonary resuscitation metric summaries (median [interquartile range]) by age: less than 1 year (38/112): chest compression fraction 0.88 (0.61-0.98), chest compression rate 119/min (110-129), and chest compression depth 2.3 cm (1.9-3.0 cm); for 1 to less than 8 years (42/112): chest compression fraction 0.94 (0.79-1.00), chest compression rate 117/min (110-124), and chest compression depth 3.8 cm (2.9-4.6 cm); for 8 to less than 18 years (32/112): chest compression fraction 0.94 (0.85-1.00), chest compression rate 117/min (110-123), chest compression depth 5.5 cm (4.0-6.5 cm). "Compliance" with guideline targets for 60-second chest compression "epochs" was predefined: chest compression fraction greater than 0.80, chest compression rate 100-120/min, and chest compression depth: greater than or equal to 3.4 cm in less than 1 year, greater than or equal to 4.4 cm in 1 to less than 8 years, and 4.5 to less than 6.6 cm in 8 to less than 18 years. Proportion of less than 1 year, 1 to less than 8 years, and 8 to less than 18 years events with greater than or equal to 60% of 60-second epochs meeting compliance (respectively): chest compression fraction was 53%, 81%, and 78%; chest compression rate was 32%, 50%, and 63%; chest compression depth was 13%, 19%, and 44%. For all events combined, total compliance (meeting all three guideline targets) was 10% (11/112). CONCLUSIONS: Across an international pediatric resuscitation collaborative, we characterized the landscape of pediatric in-hospital cardiac arrest chest compression quality metrics and found that they often do not meet 2015 American Heart Association guidelines. Guideline compliance for rate and depth in children less than 18 years is poor, with the greatest difficulty in achieving chest compression depth targets in younger children.

Comparatively Evaluating Medication Preparation Sequences for Treatment of Hyperkalemia in Pediatric Cardiac Arrest: A Prospective, Randomized, Simulation-Based Study.

OBJECTIVES: To determine whether time to prepare IV medications for hyperkalemia varied by 1) drug, 2) patient weight, 3) calcium salt, and 4) whether these data support the Advanced Cardiac Life Support recommended sequence. DESIGN: Prospective randomized simulation-based study. SETTING: Single pediatric tertiary medical referral center. SUBJECTS: Pediatric nurses and adult or pediatric pharmacists. INTERVENTIONS: Subjects were randomized to prepare medication doses for one of four medication sequences and stratified by one of three weight categories representative of a neonate/infant, child, or adult-sized adolescent: 4, 20, and 50 kg. Using provided supplies and dosing references, subjects prepared doses of calcium chloride, calcium gluconate, sodium bicarbonate, and regular insulin with dextrose. Because insulin and dextrose are traditionally prepared and delivered together, they were analyzed as one drug. Subjects preparing medications were video-recorded for the purpose of extracting timing data. MEASUREMENTS AND MAIN RESULTS: A total of 12 nurses and 12 pharmacists were enrolled. The median (interquartile range) total preparation time for the three drugs was 9.5 minutes (6.4-13.7 min). Drugs were prepared significantly faster for larger children (50 kg, 6.8 min [5.6-9.1 min] vs 20 kg, 9.5 min [8.6-13.0 min] vs 4 kg, 16.3 min [12.7-18.9 min]; p = 0.001). Insulin with dextrose took significantly longer to prepare than the other medications, and there was no difference between the calcium salts: (sodium bicarbonate, 1.9 [0.8-2.6] vs calcium chloride, 2.1 [1.2-3.1] vs calcium gluconate, 2.4 [2.1-3.0] vs insulin with dextrose, 5.1 min [3.7-7.7 min], respectively; p < 0.001). Forty-two percent of subjects (10/24) made at least one dosing error. CONCLUSIONS: Medication preparation for hyperkalemia takes significantly longer for smaller children and preparation of insulin with dextrose takes the longest. This study supports Pediatric Advanced Life Support guidelines to treat hyperkalemia during pediatric cardiac arrest similar to those recommended per Advanced Cardiac Life Support (i.e., first, calcium; second, sodium bicarbonate; and third, insulin with dextrose).

Exploration of the impact of a voice activated decision support system (VADSS) with video on resuscitation performance by lay rescuers during simulated cardiopulmonary arrest.

AIM: To assess whether access to a voice activated decision support system (VADSS) containing video clips demonstrating resuscitation manoeuvres was associated with increased compliance with American Heart Association Basic Life Support (AHA BLS) guidelines. METHODS: This was a prospective, randomised controlled trial. Subjects with no recent clinical experience were randomised to the VADSS or control group and participated in a 5-min simulated out-of-hospital cardiopulmonary arrest with another 'bystander'. Data on performance for predefined outcome measures based on the AHA BLS guidelines were abstracted from videos and the simulator log. RESULTS: 31 subjects were enrolled (VADSS 16 vs control 15), with no significant differences in baseline characteristics. Study subjects in the VADSS were more likely to direct the bystander to: (1) perform compressions to ventilations at the correct ratio of 30:2 (VADSS 15/16 (94%) vs control 4/15 (27%), p=<0.001) and (2) insist the bystander switch compressor versus ventilator roles after 2 min (VADSS 12/16 (75%) vs control 2/15 (13%), p=0.001). The VADSS group took longer to initiate chest compressions than the control group: VADSS 159.5 (±53) s versus control 78.2 (±20) s, p<0.001. Mean no-flow fractions were very high in both groups: VADSS 72.2% (±0.1) versus control 75.4 (±8.0), p=0.35. CONCLUSIONS: The use of an audio and video assisted decision support system during a simulated out-of-hospital cardiopulmonary arrest prompted lay rescuers to follow cardiopulmonary resuscitation (CPR) guidelines but was also associated with an unacceptable delay to starting chest compressions. Future studies should explore: (1) if video is synergistic to audio prompts, (2) how mobile technologies may be leveraged to spread CPR decision support and (3) usability testing to avoid unintended consequences.

Cardiopulmonary Resuscitation During Simulated Pediatric Interhospital Transport: Lessons Learned From Implementation of an Institutional Curriculum.

INTRODUCTION: Little is known about cardiopulmonary resuscitation (CPR) quality during pediatric interhospital transport; hence, our aim was to investigate its feasibility. METHODS: After implementing an institutional education curriculum on pediatric resuscitation during ambulance transport, we conducted a 4-year prospective observational study involving simulation events. Simulated scenarios were (1) interhospital transport of a child retrieved in cardiac arrest (Sim1) and (2) unanticipated cardiac arrest of a child during transport (Sim2). Cardiopulmonary resuscitation data were collected via Zoll RSeries defibrillators. Performance was evaluated using age-appropriate American Heart Association (AHA) Guidelines. Video recordings were reviewed for qualitative thematic analysis. RESULTS: Twenty-six simulations were included: 16 Sim1 [mannequins: Laerdal SimMan 3G (n = 13); Gaumard 5-year-old HAL (n = 3)] and 10 Sim2 [Gaumard 1-year-old HAL (n = 8); Laerdal SimBaby (n = 2)]. Median (IQR) CPR duration was 18 minutes 23 seconds (14-22 minutes), chest compression rate was 112 per minute (106-118), and fraction (CCF) was 1 (0.9-1). Five hundred eight 60-second resuscitation epochs were evaluated (Sim1: 356; Sim2: 152); 73% were AHA compliant for rate and 87.8% for CCF. Twenty-four minutes (4.7%) had pauses more than 10 seconds. One hundred fifty seven Sim1 epochs (44.1%) met criteria for excellent CPR (AHA-compliant for rate, depth, and CCF). Rates of excellent CPR were higher for learner groups with increased simulation and transport experience (59.1% vs. 35.3%, P < 0.001). Thematic analysis identified performance-enhancing strategies, stemming from anticipating challenges, planning solutions, and ensuring team's shared mental model. CONCLUSIONS: High-quality CPR may be achievable during pediatric interhospital transport. Certain transport-specific strategies may enhance resuscitation quality. Learners' performance improved with simulation and transport experience, highlighting ongoing education's role.

Using the Opportunity Estimator tool to improve engagement in a quality and safety intervention.

Teams throughout the United States participating in a program to reduce central line-associated bloodstream infections (CLABSIs) are using the Opportunity Estimator. This web-based tool translates CLABSI-related data into "opportunity estimates" of the patient lives and money that could be saved by reducing these infections.

Association of end-tidal carbon dioxide levels during cardiopulmonary resuscitation with survival in a large paediatric cohort.

AIM: To examine the associations between ETCO2, ROSC, and chest compression quality markers in paediatric patients during active resuscitation. METHODS: This was a single-centre cohort study of data collected as part of an institutional prospective quality initiative improvement program that included all paediatric patients who received chest compressions of any duration from January 1, 2013, through July 10, 2018, in the Johns Hopkins Children's Center. Data was collected from Zoll R Series® defibrillators. Events were included if Zoll data files contained both chest compression and ETCO2 data. 2,746 minutes corresponding to 143 events were included in the analyses. RESULTS: The median event ETCO2 for all 143 events was 16.8 [9.3-26.3] mmHg. There was a significant difference in median event ETCO2 between events that achieved ROSC and those that did not (ROSC: 19.3 [14.4-26.6] vs. NO ROSC: 13.9 [6.6-25.5] mmHg; p < 0.05). When the events were based on patient age, this relationship held in adolescents (ROSC: 18.8 [15.5-22.3] vs. NO ROSC: 9.6 [4.4-15.9] mmHg; p < 0.05), but not in children or infants. Median event ETCO2 was significantly associated with chest compression rate less than 140 (p < 0.0001) and chest compression fraction 90-100 (p < 0.0001). CONCLUSIONS: This represents the largest collection of ETCO2 and chest compression data in paediatric patients to date and unadjusted analyses suggests an association between ETCO2 and ROSC in some paediatric patients.

Simulated pediatric resuscitation use for personal protective equipment adherence measurement and training during the 2009 influenza (H1N1) pandemic.

BACKGROUND: Previous experience with simulated pediatric cardiac arrests (that is, mock codes) suggests frequent deviation from American Heart Association (AHA) basic and advanced life support algorithms. During highly infectious outbreaks, acute resuscitation scenarios may also increase the risk of insufficient personal protective equipment (PPE) use by health care workers (HCWs). Simulation was used as an educational tool to measure adherence with PPE use and pediatric resuscitation guidelines during simulated cardiopulmonary arrests of 2009 influenza A patients. METHODS: A retrospective, observational study was performed of 84 HCWs participating in 11 in situ simulations in June 2009. Assessment included (1) PPE adherence, (2) confidence in PPE use, (3) elapsed time to specific resuscitation maneuvers, and (4) deviation from AHA guidelines. RESULTS: Observed adherence with PPE use was 61% for eye shields, 81% for filtering facepiece respirators or powered air-purifying respirators, and 87% for gown/gloves. Use of a "gatekeeper" to control access and facilitate donning of PPE was associated with 100% adherence with gown and respirator precautions and improved respirator adherence. All simulations showed deviation from pediatric basic life support protocols. The median time to bag-valve-mask ventilation improved from 4.3 to 2.7 minutes with a gatekeeper present. Rapid isolation carts appeared to improve access to necessary PPE. Confidence in PPE use improved from 64% to 85% after the mock code and structured debriefing. CONCLUSIONS: Large gaps exist in the use of PPE and self-protective behaviors, as well as adherence to resuscitation guidelines, during simulated resuscitation events. Intervention opportunities include use of rapid isolation measures, use of gatekeepers, reinforcement of first responder roles, and further simulation training with PPE.

Factors Associated With Pediatric Emergency Airway Management by the Difficult Airway Response Team.

Background The goal of this study was to determine if difficult airway risk factors were similar in children cared for by the difficult airway response team (DART) and those cared for by the rapid response team (RRT). Methods In this retrospective database analysis of prospectively collected data, we analyzed patient demographics, comorbidities, history of difficult intubation, and intubation event details, including time and place of the emergency and devices used to successfully secure the airway. Results Within the 110-patient cohort, median age (IQR) was higher among DART patients than among RRT patients [8.5 years (0.9-14.6) versus 0.3 years (0.04-3.6); P < 0.001]. The odds of DART management were higher for children ages 1-2 years (aOR, 43.3; 95% CI: 2.73-684.3) and >5 years (aOR, 13.1; 95% CI: 1.85-93.4) than for those less than one-year-old. DART patients were more likely to have craniofacial abnormalities (aOR, 51.6; 95% CI: 2.50-1065.1), airway swelling (aOR, 240.1; 95% CI: 13.6-4237.2), or trauma (all DART managed). Among patients intubated by the DART, children with a history of difficult airway were more likely to have musculoskeletal (P = 0.04) and craniofacial abnormalities (P < 0.001), whereas children without a known history of difficult airway were more likely to have airway swelling (P = 0.04). Conclusion Specific clinical risk factors predict the need for emergency airway management by the DART in the pediatric hospital setting. The coordinated use of a DART to respond to difficult airway emergencies may limit attempts at endotracheal tube placement and mitigate morbidity.

Using evidence, rigorous measurement, and collaboration to eliminate central catheter-associated bloodstream infections.

Healthcare-associated infections are common, costly, and often lethal. Although there is growing pressure to reduce these infections, one project thus far has unprecedented collaboration among many groups at every level of health care. After this project produced a 66% reduction in central catheter-associated bloodstream infections and a median central catheter-associated bloodstream infection rate of zero across >100 intensive care units in Michigan, the Agency for Healthcare Research and Quality awarded a grant to spread this project to ten additional states. A program, called On the CUSP: Stop BSI, was formulated from the Michigan project, and additional funding from the Agency for Healthcare Research and Quality and private philanthropy has positioned the program for implementation state by state across the United States. Furthermore, the program is being implemented throughout Spain and England and is undergoing pilot testing in several hospitals in Peru. The model in this program balances the tension between being scientifically rigorous and feasible. The three main components of the model include translating evidence into practice at the bedside to prevent central catheter-associated bloodstream infections, improving culture and teamwork, and having a data collection system to monitor central catheter-associated bloodstream infections and other variables. If successful, this program will be the first national quality improvement program in the United States with quantifiable and measurable goals.

Emergency Department Ergonomic Redesign Improves Team Satisfaction in Cardiopulmonary Resuscitation Delivery: A Simulation-Based Quality Improvement Approach.

BACKGROUND: Delivering high-quality cardiopulmonary resuscitation (CPR) requires teams to administer highly choreographed care. The American Heart Association recommends audiovisual feedback for real-time optimization of CPR performance. In our Emergency Department (ED) resuscitation bays, ZOLL cardiac resuscitation device visibility was limited. OBJECTIVE: To optimize the physical layout of our resuscitation rooms to improve cardiac resuscitation device visibility for real-time CPR feedback. METHODS: A simulated case of cardiac arrest with iterative ergonomic modifications was performed four times. Variables included the locations of the cardiac resuscitation device and of team members. Participants completed individual surveys and provided qualitative comments in a group debriefing. The primary outcome of interest was participants' perception of cardiac resuscitation device visibility. RESULTS: The highest scoring layout placed the cardiac resuscitation device directly across from the compressor and mirrored the device screen to a television mounted at the head of the bed. Comparing this configuration to our standard configuration on a five-point Likert scale, cardiac resuscitation device visibility increased 46.7% for all team members, 150% for the team leader, and 179% for team members performing chest compressions. CONCLUSION: An iterative, multidisciplinary, simulation-based approach can improve team satisfaction with important clinical care factors when caring for patients suffering cardiac arrest in the ED.

Saving Lives and Improving the Quality of Pediatric Resuscitation Across the World: A 1-Day Research Accelerator Hosted by the International Network for Simulation-based Pediatric Innovation, Research, and Education and the International Pediatric Simulation Society.

STATEMENT: The International Network for Simulation-based Pediatric Innovation, Research, and Education co-hosted a novel research accelerator meeting with the International Pediatric Simulation Society in May of 2019 in Toronto. The purpose of the meeting was to bring together healthcare simulation scientists with resuscitation stakeholders to brainstorm strategies for accelerating progress in the science of saving pediatric lives from cardiac arrest. This was achieved by working in teams to draft targeted requests for proposals calling the research community to action investigating this topic. During the 1-day meeting, groups were divided into 6 teams lead by experts representing specific domains of simulation research. Teams developed a pitch and presented a sample request for proposals to a panel of expert judges, making a case for why their domain was the most important to create a funding opportunity. The winner of the competition had their specific request for proposal turned into an actual funding opportunity, supported by philanthropy that was subsequently disseminated through International Network for Simulation-based Pediatric Innovation, Research, and Education as a competitive award. An inspired donor supported an award for the second-place proposal as well, evidence of early research acceleration catalyzed from this conference. This article is a summary of the meeting rationale, format, and a description of the requests for proposals that emerged from the meeting. Our goal is to inspire other stakeholders to use this document that leverages simulation and resuscitation science expertise, as the framework to create their own funding opportunities, further accelerating pediatric resuscitation research, ultimately saving the lives of more children worldwide.

Standardising communication to improve in-hospital cardiopulmonary resuscitation.

AIM: Recommendations for standardised communication to reduce chest compression (CC) pauses are lacking. We aimed to achieve consensus and evaluate feasibility and efficacy using standardised communication during cardiopulmonary resuscitation (CPR) events. METHODS: Modified Delphi consensus process to design standardised communication elements. Feasibility was pilot tested in 16 simulated CPR scenarios (8 scenarios with physician team leaders and 8 with chest compressors) randomized (1:1) to standardised [INTERVENTION] vs. closed-loop communication [CONTROL]. Adherence and efficacy (duration of CC pauses for defibrillation, intubation, rhythm check) was assessed by audiovisual recording. Mental demand and frustration were assessed by NASA task load index subscales. RESULTS: Consensus elements for standardised communication included: 1) team preparation 15-30 s before CC interruption, 2) pre-interruption countdown synchronized with last 5 CCs, 3) specific action words for defibrillation, intubation, and interrupting/resuming CCs. Median (Q1,Q3) adherence to standardised phrases was 98% (80%,100%). Efficacy analysis showed a median [Q1,Q3] peri-shock pause of 5.1 s. [4.4; 5.8] vs. 7.5 s. [6.3; 8.8] seconds, p < 0.001, intubation pause of 3.8 s. [3.6; 5.0] vs. 6.9 s. [4.8; 10.1] seconds, p = 0.03, rhythm check pause of 4.2 [3.2,5.7] vs. 8.6 [5.0,10.5] seconds, p < 0.001, median frustration index of 10/100 [5,20] vs. 35/100 [25,50], p < 0.001, and median mental demand load of 55/100 [30,70] vs. 65/100 [50,85], p = 0.41 for standardised vs. closed loop communication. CONCLUSION: This pilot study demonstrated feasibility of using consensus-based standardised communication that was associated with shorter CC pauses for defibrillation, intubation, and rhythm checks without increasing frustration index or mental demand compared to current best practice, closed loop communication.

Best Practices and Theoretical Foundations for Simulation Instruction Using Rapid-Cycle Deliberate Practice.

STATEMENT: Rapid-cycle deliberate practice (RCDP) is a learner-centered simulation instructional strategy that identifies performance gaps and targets feedback to improve individual or team deficiencies. Learners have multiple opportunities to practice observational, deductive, decision-making, psychomotor, and crisis resource management skills. As its implementation grows, simulationists need to have a shared mental model of RCDP to build high-quality RCDP-based initiatives. To compare and make general inferences from RCDP data, each training needs to follow a similar structure. This article seeks to describe the fundamentals of RCDP, including essential components and potential variants. We also summarize the current published evidence regarding RCDP's effectiveness. This article serves to create a shared understanding of RCDP, provide clear definitions and classifications for RCDP research, and provide options for future RCDP investigation.

Cold Debriefings after In-hospital Cardiac Arrest in an International Pediatric Resuscitation Quality Improvement Collaborative.

INTRODUCTION: Clinical event debriefing functions to identify optimal and suboptimal performance to improve future performance. "Cold" debriefing (CD), or debriefing performed more than 1 day after an event, was reported to improve patient survival in a single institution. We sought to describe the frequency and content of CD across multiple pediatric centers. METHODS: Mixed-methods, a retrospective review of prospectively collected in-hospital cardiac arrest (IHCA) data, and a supplemental survey of 18 international institutions in the Pediatric Resuscitation Quality (pediRES-Q) collaborative. Data from 283 IHCA events reported between February 2016 and April 2018 were analyzed. We used a Plus/Delta framework to collect debriefing content and performed a qualitative analysis utilizing a modified Team Emergency Assessment Measurement Framework. Univariate and regression models were applied, accounting for clustering by site. RESULTS: CD occurred in 33% (93/283) of IHCA events. Median time to debriefing was 26 days [IQR 11, 41] with a median duration of 60 minutes [20, 60]. Attendance was variable across sites (profession, number per debriefing): physicians 12 [IQR 4, 20], nurses 1 [1, 6], respiratory therapists 0 [0, 1], and administrators 1 [0, 1]. "Plus" comments reported per event were most commonly clinical standards 47% (44/93), cooperation 29% (27/93), and communication 17% (16/93). "Delta" comments were in similar categories: clinical standards 44% (41/93), cooperation 26% (24/93), and communication 14% (13/93). CONCLUSIONS: CDs were performed after 33% of cardiac arrests in this multicenter pediatric IHCA collaborative. The majority of plus and delta comments could be categorized as clinical standards, cooperation and communication.

Pediatric Critical Care Simulation Curriculum: Training Nurse Practitioners to Lead in the Management of Critically Ill Children.

INTRODUCTION: Acute care pediatric nurse practitioners have become frontline providers in the critical care environment and are expected to provide leadership in acutely critical situations. We describe a 2-day, high-fidelity, simulation-based curriculum focused on training the pediatric nurse practitioners for leadership in critical care scenarios. METHOD: This prospective pre-post interventional study used simulation-based pedagogy. Knowledge tests, time-to-task, and a follow-up survey were used to determine the effectiveness of the training. RESULTS: Participants (n = 23) improved their knowledge scores by 27% (pretest: 35.2% [standard deviation = 12.1%]; posttest: 62.2% [standard deviation = 13.8%], p < .001). In addition, time-to-task for resuscitation variables improved significantly. At 3 months, 100% of the participants who responded either agreed (15.4%) or strongly agreed (84.6%) that the boot camp prepared them to lead in a critical emergency. DISCUSSION: Simulation-based training is an effective strategy for educating critical care pediatric nurse practitioners and improves their ability to manage pediatric emergencies rapidly, which can be lifesaving.