Headpulse measurement can reliably identify large-vessel occlusion stroke in prehospital suspected stroke patients: Results from the EPISODE-PS-COVID study.

BACKGROUND: Large-vessel occlusion (LVO) stroke represents one-third of acute ischemic stroke (AIS) in the United States but causes two-thirds of poststroke dependence and >90% of poststroke mortality. Prehospital LVO stroke detection permits efficient emergency medical systems (EMS) transport to an endovascular thrombectomy (EVT)-capable center. Our primary objective was to determine the feasibility of using a cranial accelerometry (CA) headset device for prehospital LVO stroke detection. Our secondary objective was development of an algorithm capable of distinguishing LVO stroke from other conditions. METHODS: We prospectively enrolled consecutive adult patients suspected of acute stroke from 11 study hospitals in four different U.S. geographical regions over a 21-month period. Patients received device placement by prehospital EMS personnel. Headset data were matched with clinical data following informed consent. LVO stroke diagnosis was determined by medical chart review. The device was trained using device data and Los Angeles Motor Scale (LAMS) examination components. A binary threshold was selected for comparison of device performance to LAMS scores. RESULTS: A total of 594 subjects were enrolled, including 183 subjects who received the second-generation device. Usable data were captured in 158 patients (86.3%). Study subjects were 53% female and 56% Black/African American, with median age 69 years. Twenty-six (16.4%) patients had LVO and 132 (83.6%) were not LVO (not-LVO AIS, 33; intracerebral hemorrhage, nine; stroke mimics, 90). COVID-19 testing and positivity rates (10.6%) were not different between groups. We found a sensitivity of 38.5% and specificity of 82.7% for LAMS ≥ 4 in detecting LVO stroke versus a sensitivity of 84.6% (p < 0.0015 for superiority) and specificity of 82.6% (p = 0.81 for superiority) for the device algorithm (CA + LAMS). CONCLUSIONS: Obtaining adequate recordings with a CA headset is highly feasible in the prehospital environment. Use of the device algorithm incorporating both CA and LAMS data for LVO detection resulted in significantly higher sensitivity without reduced specificity when compared to the use of LAMS alone.

Comparison of Four Methods of Paramedic Continuing Education in the Management of Pediatric Emergencies.

Introduction: Finite resources limit the amount of time EMS agencies can dedicate to continuing education in pediatric emergencies. EMS instructors need effective, efficient, and affordable educational strategies for these high-risk, low frequency events.Objective: To compare the effectiveness of four training methods in management of pediatric emergencies for paramedics.Methods: A validated, performance-based, simulated clinical assessment module was used to provide a baseline measurement of paramedics' resuscitation skills during three simulated pediatric emergencies. Educational modules were developed that targeted deficiencies identified by the baseline assessment, including advanced pediatric life support skills, airway management, use of the Broselow-Luten Tape®, pediatric drug dose calculations and drug delivery, seizure management, and trauma assessment. Paramedics from five EMS agencies in Michigan were randomized to four education intervention groups. The control group used an existing, online, continuing education course. Three experimental groups were exposed to the same content during five, one-hour sessions conducted over 2.5 years. Instruction was delivered using high-fidelity, simulated case-based training, low-fidelity simulation training, or lecture with procedural skills lab, based on group assignment. After the training, all groups were tested within 4-6 months using methods identical to baseline testing.Results: One hundred forty-seven subjects completed the study. There were no differences in baseline skill levels among the four groups. Only the low fidelity simulation training group demonstrated improvement of combined scenario scores (p = 0.0008). Scores for targeted skills improved in one scenario in the high-fidelity group, two in the low-fidelity group, one in the lecture/lab group, and none in the control group.Conclusions: Although improvements in those skills included in the training were found in three groups, two hours of training in pediatric emergencies per year was insufficient to produce a substantial improvement overall. Expensive, high-fidelity simulators were not necessary for teaching pediatric resuscitation skills to paramedics; instructive scenarios using low-fidelity manikins and debriefings appear to be adequate. The content delivered by an online refresher course did not provide any improvement in performance as measured by simulated, case-based assessments.

An Innovative Inexpensive Portable Pulmonary Edema Intubation Simulator.

Audience: This pulmonary edema intubation simulator is designed to instruct paramedics, medical students, emergency medicine residents, emergency medical services fellows, and attending physicians. Introduction: Acute pulmonary edema results in respiratory distress and may require endotracheal intubation. On occasion, pulmonary edema can result in copious amounts of pink, frothy sputum in the airway, complicating intubation by hindering the intubator's view. Although airway management skills are frequently taught in a simulation setting, the frothy sputum seen in acute pulmonary edema is not easily replicated. Several articles have been published in reference to simulation model development for difficult airway management due to emesis obscuring the view of the glottic opening.1,2 There is, however, a scarcity of literature describing pulmonary edema airway management simulator construction, with only one other model identified on our review of the literature, which utilized cadavers, baking soda, vinegar, and red food coloring.3In our simulation center, we teach a variety of learners who may be called upon to care for patients in acute pulmonary edema in their clinical practice, including medical students, residents from various specialties, practicing physicians and pre-hospital personnel. We wished to familiarize these trainees with the challenges associated with intubating patients with significant frothy secretions within the hypopharynx by developing a dynamic, realistic, portable and inexpensive model to simulate the airway manifestations associated with acute pulmonary edema. Educational Objectives: By the end of the session, learners will be able to: 1. Discuss the pathophysiology of, and immediate stabilization management steps for, acute cardiogenic pulmonary edema. 2. List the indications, contraindications, and risks associated with intubating a patient with acute cardiogenic pulmonary edema. 3. Demonstrate effective communication and teamwork skills to manage the airway of a simulated patient in respiratory distress due to acute cardiogenic pulmonary edema. 4. Successfully and safely intubate a simulated patient with a difficult airway due to visual obstruction from frothy pulmonary edema secretions. Educational Methods: We adapted a previously owned commercial airway task trainer simulator using an aquarium pump, tubing, an air stone, and an endotracheal tube. Pulmonary edema solution was created with glycerin, dish soap, (distilled) water and simulated blood. The solution and air stone are placed in one of the simulator's lungs. Subsequently, turning on the aquarium air pump generates simulated pulmonary edema within the lung itself, which froths up and out of the trachea and into the hypopharynx, mimicking the gross pathophysiological process.Learners complete pre-reading assignments prior to attending a small group didactic-practical session. Following a brief case discussion, led by the instructor, about the management of a patient in respiratory distress due to acute pulmonary edema, learners transition to a hands-on experience intubating the pulmonary edema manikin with the use of direct and video laryngoscopy, aided by a large bore Yankauer for suction and a bougie. Depending on the training level of the learners, the instructor will use judgment and may elect to demonstrate intubating the manikin using video laryngoscopy before the learners attempt the procedure. The authors recommend that the instructor use video laryngoscopy for teaching purposes so that all learners can visualize the intubation techniques (Yankauer, bougie) in the context of copious pulmonary edema fluid obscuring the glottis and surrounding airway structures.The practical portion is dedicated solely to intubation, with one learner assuming the role of the intubator and another assuming the role of a respiratory therapist, while the other leaners observe and/or provide real-time feedback. Learners rotate through these aforementioned roles. To maintain efficiency of the simulation session and maximize the number of intubation attempts each learner receives, the session is designed to begin with a case discussion about the management of a patient with acute pulmonary edema up through the timepoint of successful intubation, followed by a practical portion where the learners perform multiple intubations on the innovative pulmonary edema airway management task trainer. During the practical portion, real-time constructive feedback is given to each learner. At the end of the simulation session, a debriefing is completed.This model can be used to address several ACGME Emergency Medicine Milestones,4 specifically Milestone 9 (General Approach to Procedures - PC9), Level 4 (Performs indicated procedures on any patients with challenging features [eg, poorly identifiable landmarks, at extremes of age or with comorbid conditions], and also Milestone 10 (Airway Management - PC10), Level 4 (Performs airway management in any circumstance taking steps to avoid potential complications). This model can also be used to address ACGME Emergency Medical Services Milestones,5 specifically "Procedures Performed in the Pre-hospital Environment - Patient Care," Level 4 (Performs indicated procedures on any patients, including those with challenging features (eg, poorly identifiable landmarks, at extremes of age or with co-morbid conditions). Research Methods: At the conclusion of the session, verbal feedback is sought from each participant by the instructor: How helpful did you find this simulation experience for learning about airway management in patients with acute pulmonary edema? Did you find the pulmonary edema intubation model to be realistic? Following this simulation experience, how would you rate your personal confidence in terms of managing an airway complicated by acute pulmonary edema? Results: For under fifty dollars, we have been able to adapt one of our previously owned airway management task trainers to build a pulmonary edema intubation simulator. It has been used in a wide variety of settings for different learners, including medical students, residents, fellows and pre-hospital providers. Since the 2016-2017 academic year, two hundred and twenty-six emergency medicine residents (PGY1, PGY2, and PGY3) have successfully used our innovative pulmonary edema airway management task trainer. Qualitatively it has been well-received and felt to be realistic by both our learners and instructors based on verbal feedback received following the simulation sessions. Discussion: We are aware of only one prior report attempting to simulate the frothy sputum seen in acute pulmonary edema. Lipe, et al., described mixing baking soda, vinegar and red food coloring in a cadaver hypopharynx just prior to an intubation attempt.3 This combination creates a fizzy frothy solution that fills the hypopharynx and pushes proximally into the mouth. This model is limited by design, however, in that it was unable to mimic a true in vivo appearance of a continuous flow of pulmonary edema-like fluid from the glottic opening. We feel we were able to overcome this limitation and also believe it is important for the leaner to experience the challenges of intubation when faced with copious secretions originating from within the lower airways. Our model generates the froth from within the lung itself, and it migrates proximally, similar to the dynamic pathophysiological process that occurs in vivo. Since we did not compare these two techniques, it is unknown which is more realistic. Neither the Lipe cadaver model nor our manikin model has been validated in terms of the realistic nature of the simulated pulmonary edema fluid. This would be ripe for future investigation. Nonetheless, informal qualitative feedback from our learners and instructors has been positive.Resident use of our innovative dynamic pulmonary edema airway management task trainer has been incorporated into our Emergency Medicine residency and Emergency Medical Services fellowship Clinical Competency Committee discussions with respect to ACGME Milestone satisfaction. Our model addresses level 4 of Emergency Medicine Milestone 9 (General Approach to Procedures) and Milestone 10 (Airway Management). Additionally, level 4 of Emergency Medical Services Milestone 2 (Procedures Performed in the Pre-hospital Environment - Patient Care) is addressed. Incorporating successful intubation of the dynamic pulmonary edema airway management task trainer has provided the EM and EMS faculty with a more objective measure by which to score the aforementioned milestones during the mid-year and year-end Clinical Competency Committee meetings.Overall, this innovation has met our objectives well. We have added this model to our library of more complicated airway management scenarios, such as vomitus and aspiration. Our emergency medicine residency program hosts a version of the difficult airway course and includes this pulmonary edema simulation station as part of that course. The model is very portable, allowing us to transport it to different sites for use. It is inexpensive, costing less than $50 to construct. Finally, the design is readily adaptable to any standard airway training manikin that has a simulated hollow lung with a detachable connection to a conduit representing a bronchus, which has a direct connection with a simulated trachea into which an endotracheal tube can physically be passed. Topics: Airway management, difficult airway, intubation, obstructed airway, pulmonary edema, video laryngoscopy, visual obstruction.

Errors and error-producing conditions during a simulated, prehospital, pediatric cardiopulmonary arrest.

INTRODUCTION: Management of pediatric cardiac arrest challenges the skills of prehospital care providers. Errors and error-producing conditions are difficult to identify from retrospective records. The objective of this study was to identify errors committed by prehospital care providers and the underlying causes of those errors during a simulated pediatric cardiopulmonary arrest followed by a structured debriefing. METHODS: Performance criteria were defined prospectively by an advisory panel. Prehospital care providers from 6 emergency medical service agencies in Michigan participated in a simulation of an infant cardiopulmonary arrest using their own drugs, equipment, and protocols in a mobile trailer. Simulations were video recorded and played back during debriefings that were conducted immediately after the event to facilitate error analysis. Observed errors and subjects' explanations were analyzed by thematic qualitative assessment methods and descriptive statistics. RESULTS: One hundred ninety-four subjects, including paramedics, emergency medical technicians, and emergency medical responders in various crew configurations, participated in 60 simulation sessions during a 5-month period (April to August of 2010). Error types were classified into 4 clinically important themes as follows: failure to provide adequate ventilation, failure to provide effective circulation, failure to achieve vascular access rapidly, and medication errors. Multiple underlying causes of medication dosing and other errors were identified, including cognitive, procedural, communication, teamwork, and systems factors. CONCLUSIONS: We systematically observed many types of errors and identified some of the underlying causes during a simulated, prehospital, pediatric cardiopulmonary arrest. There were numerous, multifactorial, and sometimes, synergistic causes of medication dosing errors. Emergency medical service officials can use these findings to prevent future errors.

Medication dosing errors in pediatric patients treated by emergency medical services.

BACKGROUND: Medication dosing errors occur in up to 17.8% of hospitalized children. There are limited data to describe pediatric medication errors by emergency medical services (EMS) paramedics. It has been shown that paramedics have infrequent encounters with pediatric patients. OBJECTIVE: To characterize medication dosing errors in children treated by EMS. METHODS: We studied patients aged ≤11 years who were treated by paramedics from eight Michigan EMS agencies from January 2004 through March 2006. We defined a medication dosing error as ≥20% deviation from the weight-appropriate dose, as determined by the patient's reported weight in the prehospital medical record or by use of the Broselow-Luten tape (BLT). We studied errors in administering six EMS medications commonly given to children: albuterol, atropine, dextrose, diphenhydramine, epinephrine, and naloxone. RESULTS: There were 5,547 children aged ≤11 years who were treated during the study period, of whom 230 (4.1%) received drugs and had a documented weight. These patients received a total of 360 medication administrations. Multiple drug administrations occurred in 73 cases. Medication dosing errors occurred in 125 of the 360 drug administrations (34.7%; 95% confidence interval [CI] 30.0, 39.8). Relative drug dosage errors (with 95% CI) were as follows: albuterol 23.3% (18.4, 29.1), atropine 48.8% (34.3, 63.5), diphenhydramine 53.8% (29.1, 76.8), and epinephrine 60.9% (49.9, 73.9). The mean error (± standard deviation) for intravenous/intraosseous 1:1000 epinephrine overdoses was 808% ± 428%. The mean error (± standard deviation) for intravenous/intraosseous 1:1000 epinephrine underdoses was 35.5% ± 27.4%. CONCLUSIONS: Medications delivered in the prehospital care of children were frequently administered outside of the proper dose range when compared with patient weights recorded in the prehospital medical record. EMS systems should develop strategies to reduce pediatric medication dosing errors.

Simulation-based assessment of paramedic pediatric resuscitation skills.

BACKGROUND: Emergency medical services (EMS) providers infrequently encounter seriously ill and injured pediatric patients. Clinical simulations are useful for assessing skill level, especially for low-frequency, high-risk problems. OBJECTIVE: To identify the most common performance deficiencies in paramedics' management of three simulated pediatric emergencies. METHODS: Paramedics from five EMS agencies in Michigan were eligible subjects for this prospective, observational study. Three clinical assessment modules (CAMs) were designed and validated using pediatric simulators with varying technologic complexity. Scenarios included an infant cardiopulmonary arrest, sepsis/seizure, and child asthma/respiratory arrest. Each scenario required paramedics to perform an assessment and provide appropriate pediatric patient care within a 12-minute time limit. Trained instructors conducted the simulations by following strict guidelines for sequences of events and responses. Videos of CAMs were reviewed by an independent evaluator to verify scoring accuracy. Percentage of steps completed for each of the three scenarios and specific performance deficiencies were recorded. RESULTS: Two hundred twelve paramedics completed the CAMs. The average percentages of steps completed were as follows: arrest CAM, 45.3%; asthma CAM, 51.6%; and sepsis CAM, 47.1%. Performance deficiencies included lack of airway support or protection; lack of support of ventilations or cardiac function; inappropriate use of length-based treatment tapes; and inaccurate calculation and administration of medications and fluids. CONCLUSION: Multiple deficiencies in paramedics' performance of pediatric resuscitation skills were objectively identified using three manikin-based simulations. EMS educators and EMS medical directors should target these specific skill deficiencies when developing continuing education in prehospital pediatric patient care.

The use of a photoionization detector to detect harmful volatile chemicals by emergency personnel.

OBJECTIVE: The objective of this investigation was to determine if a photoionization detector (PID) could be used to detect the presence of a simulated harmful chemical on simulated casualties of a chemical release. METHODS: A screening protocol, based on existing radiation screening protocols, was developed for the purposes of the investigation. Three simulated casualties were contaminated with a simulated chemical agent and two groups of emergency responders were involved in the trials. The success-failure ratio of the participants was used to judge the performance of the PID in this application. RESULTS: A high success rate was observed when the screening protocol was properly adhered to (97.67%). Conversely, the success rate suffered when participants deviated from the protocol (86.31%). With one exception, all failures were noted to have been the result of a failure to correctly observe the established screening protocol. CONCLUSIONS: The results of this investigation indicate that the PID may be an effective screening tool for emergency responders. However, additional study is necessary to both confirm the effectiveness of the PID and refine the screening protocol if necessary.