Simulation in pediatric anesthesiology: current state and visions for the future.

PURPOSE OF REVIEW: Simulation is a well established practice in medicine. This review reflects upon the role of simulation in pediatric anesthesiology in three parts: training anesthesiologists to care for pediatric patients safely and effectively; evaluating and improving systems of care for children; and visions for the future. RECENT FINDINGS: Simulation continues to prove a useful modality to educate both novice and experienced clinicians in the perioperative care of infants and children. It is also a powerful tool to help analyze and improve upon how care is provided to infants and children. Advances in technology and computational power now allow for a greater than ever degree of innovation, accessibility, and focused reflection and debriefing, with an exciting outlook for promising advances in the near future. SUMMARY: Simulation plays a key role in developing and achieving peak performance in the perioperative care of infants and children. Although simulation already has a great impact, its full potential is yet to be harnessed.

The evolution of surgical virtual education and telementoring: One surgeon's journey.

The first era of the global proliferation of surgical advancements involved surgical infection rate and technique breakthroughs by Lister, Halsted, and others. This was propagated by letters, academic papers, and international visits. While success was achieved, it was at a suboptimal pace. In the current era of minimally invasive surgical approaches, these methods are inadequate. This paper chronicles the development and application of virtual learning and telementoring as force multipliers to speed procedural adoption and proliferation.

Robotic Surgery: The Impact of Simulation and Other Innovative Platforms on Performance and Training.

OBJECTIVE: To review the current status of robotic training and the impact of various training platforms on the performance of robotic surgical trainees. DATA SOURCES: Literature review of Google Scholar and PubMed. The search terms included a combination of the following: "robotic training," "simulation," "robotic curriculum," "obgyn residency robotic training," "virtual reality robotic training," "DaVinci training," "surgical simulation," "gyn surgical training." The sources considered for inclusion included peer-reviewed articles, literature reviews, textbook chapters, and statements from various institutions involved in resident training. METHODS OF STUDY SELECTION: A literature search of Google Scholar and PubMed using terms related to robotic surgery and robotics training, as mentioned in the "Data Sources" section. RESULTS: Multiple novel platforms that use machine learning and real-time video feedback to teach and evaluate robotic surgical skills have been developed over recent years. Various training curricula, virtual reality simulators, and other robotic training tools have been shown to enhance robotic surgical education and improve surgical skills. The integration of didactic learning, simulation, and intraoperative teaching into more comprehensive training curricula shows positive effects on robotic skills proficiency. Few robotic surgery training curricula have been validated through peer-reviewed study, and there is more work to be completed in this area. In addition, there is a lack of information about how the skills obtained through robotics curricula and simulation translate into operating room performance and patient outcomes. CONCLUSION: Data collected to date show promising advances in the training of robotic surgeons. A diverse array of curricula for training robotic surgeons continue to emerge, and existing teaching modalities are evolving to keep up with the rapidly growing demand for proficient robotic surgeons. Futures areas of growth include establishing competency benchmarks for existing training tools, validating existing curricula, and determining how to translate the acquired skills in simulation into performance in the operating room and patient outcomes. Many surgical training platforms are beginning to expand beyond discrete robotic skills training to procedure-specific and team training. There is still a wealth of research to be done to understand how to create an effective training experience for gynecologic surgical trainees and robotics teams.

Using Simulation to Teach Home Health Care.

To describe development, use and outcomes of a Home Healthcare (HHC) simulation experience. Quasi-experimental pre/posttest. Setting: A simulation center for nursing students (N = 108) completing an 8-hour simulation experience, followed by data collection on perceived benefits to their learning; and influence on their desire to work in HHC. 93% (n = 101) reported the simulation was helpful; 57.4% (n = 62) reported participation increased their desire to work in HHC. Use of a HHC-focused simulation had positive learning outcomes in this setting. In this sample, results suggest value in maintaining the simulation experience for future cohorts.

Simulation and student learning: will NMC policy lead to lasting change?

Emeritus Professor Alan Glasper, from the University of Southampton, discusses a new initiative from the Nursing and Midwifery Council to increase clinical learning through simulation during the COVID-19 pandemic.

Educating Perioperative Nurses About Local Anesthetic Systemic Toxicity Using High-Fidelity Simulation.

BACKGROUND: The rarity of perianesthetic catastrophic events creates a challenge in training support staff in the treatment of emergencies such as local anesthetic systemic toxicity (LAST). Simulation learning offers a unique venue in which to safely encounter rare events. AIMS: This study aimed to evaluate knowledge retention regarding LAST in perianesthetic nursing staff using high-fidelity simulation and a short didactic session. DESIGN: Nurses were recruited from perioperative locations to participate in a simulated scenario of LAST and engage in a short didactic session. SETTINGS: Simulation and education occurred in the high-fidelity simulation center at the University of Wisconsin Hospital. PARTICIPANTS/SUBJECTS: Thirteen nurses from the preoperative, post-anesthesia, and block nursing teams participated in the study. METHODS: Participants completed a pre-test before participating in the simulation, followed by a formal debrief and short lecture. They then completed post-tests and a short survey focused on self-efficacy and review of the simulation experience. RESULTS: Test scores, compared to the pre-test, improved significantly on the immediately-post, 1-month, and 3-month assessments. Participants felt more equipped to handle crisis scenarios. CONCLUSIONS: Experiential learning often results in significant knowledge acquisition and retention. Participants in this study improved their test scores regarding LAST and increased their sense of self-efficacy and ability to handle crisis scenarios after taking part in a high-fidelity simulation.

Effects of a Simulation With Team-Based Learning on Knowledge, Team Performance, and Teamwork for Nursing Students.

Simulation and team-based learning are reported as useful strategies in nursing education. However, empirical evidence on the effects of participating in an integrated course of team-based learning and simulation is limited. The aim of this study was to identify the effects of a nursing simulation program with team-based learning on knowledge, team performance, and teamwork among Korean nursing students. A one-group pretest-posttest design was used. Fourth-year students (N = 229) participated in a 32-hour nursing simulation program with team-based learning. Each of the three sessions of the program involved a 3-hour task training with video-assisted learning and skills performance assessment, 1-hour team-based learning, and 4-hour simulation session with a high-fidelity simulator. In addition to the knowledge test and performance assessment, participants completed a self-administered questionnaire on teamwork. Participants achieved higher scores in the Group Readiness Assurance Test than they did in the Individual Readiness Assurance Test. The posttest scores on team performance and teamwork were significantly higher than their pretest scores. The simulation with team-based learning induced favorable effects on participants' knowledge, performance, and teamwork. A curricular integration of simulation program with team-based learning is consistent with achieving outcomes-based learning in nursing education.

Cadaverless anatomy: Darkness in the times of pandemic Covid-19.

The pandemic Covid-19 is responsible for a major education crisis globally and has a drastic impact on medical training as well. The objective of the present study was to envision the present and future impact of Covid-19 on anatomy learning and research. The virtual education is the only mode of teaching in current scenario. Every anatomist is unlocking technology to deliver best education however understanding of the subject without dissections or other practical teaching aids like bones, specimens, embryology models, microscopic slides etc. is challenging. This approach misses the feel and human visual impacts. Potential educational disruption is felt currently and will be experienced even after the pandemic is over due to scarcity of cadavers. As the body donor may be carrier or died of Covid-19 and there is no proven screening to rule out this infection in donor, so the acceptance of body donations is not advisable for the safety of medical students and health care workers. To conclude, anatomy education is cadaverless currently due to Covid-19 lockdown and it is prophesied that after the pandemic, real cadavers will be replaced by virtual cadavers because of paucity of cadavers. Research in the field of anatomy will also be adversely affected.

[Virtual arthroscopy : Gaming or training concept of the future]. / Virtuelle Arthroskopie : Computerspiel oder Weiterbildungskonzept der Zukunft?

Arthroscopy is a technically challenging surgical procedure with a relatively shallow learning curve compared to open procedures. To become an expert special cognitive and manual abilities have to be acquired and trained. The current situation in further medical education combined with the increasing economic pressure in the medical field does not leave enough room for a time-consuming training in arthroscopic techniques. A structured simulation training could be an alternative solution to this problem. The benefits of arthroscopic simulation training are meanwhile well documented. The complex tasks that an expert carries out during arthroscopy can be fragmented into more simple and elementary exercises and can be trained in a stress-free environment outside the operation room. An essential advantage of simulation training is the assessment of objective measurement parameters during the individual exercises. These parameters can be used to evaluate the learning process and performance of arthroscopic tasks. The aim of this review is to reflect the current state of simulation technology in arthroscopy and to show how simulator training can be meaningfully and effectively integrated into arthroscopic further training, exemplified by a modern medical further education concept.

Time-efficient, goal-directed, and evidence-based teaching in the ICU.

PURPOSE OF REVIEW: Teaching in the stressful, high-acuity environment of the ICU is challenging. The intensivist-educator must use teaching strategies that are both effective and time-efficient, as well as evidence-based approaches to the ICU curriculum. This review provides an overview of pertinent educational theories and their implications on educational practices, a selection of effective teaching techniques, and a review on feedback. RECENT FINDINGS: Evidence supports the role of conceptual frameworks in providing the educator with a key perspective to obtain a deeper understanding of the factors contributing to an effective and goal-directed education in the ICU. The role of simulation training for technical and nontechnical skills acquisition is growing. Feedback is difficult to provide, but critical to facilitate learner success; frameworks, and approaches are becoming more standardized. SUMMARY: Direct teaching should be goal-oriented, sequential, and adjusted to the level of the learner. The ICU curriculum should optimize cognitive load, reduce stress that is unrelated to the activity, include resilience training, and help trainees deal with stressful clinical situations better. Simulation is a powerful tool to promote technical and nontechnical skills. Providing feedback is essential and a skill that can be taught and enhanced with structure, prompts, and tools.

Simulation as a Nursing Education Disrupter.

Simulation as an evidence-based pedagogy began emerging at a time when many constraints were being imposed on clinical experiences for nursing students. As research illuminated the advantages of simulation and standards were developed, educators began to recognize the limitations of the clinical setting, such as the inability to provide experiences in teamwork and delegation, and a focus on tasks. Simulations are crafted to provide an experience that matches content that is being taught in class, and debriefing techniques guide learners in a reflective process that promotes the development of clinical reasoning and judgment. The National Council of State Boards of Nursing study concluded that simulation could be substituted for 50% of clinical hours. Simulation-exposed gaps in the curriculum and its pedagogical principles are now extending to adaptations of its use in the classroom and in clinical postconferences. They are also shaping teacher-student conversations in the office and the hallways. Use of simulation for assessment is beginning to evolve. In a little more than 10 years, it has started a revolution that will continue to have a major impact on all aspects of nursing education in the future.

Impact of distance education via interactive videoconferencing on students' course performance and satisfaction.

The impact of distance education via interactive videoconferencing on pharmacy students' performance in a course was assessed after implementation of a distance campus. Students filled out a "Student Demographic Survey" and a "Precourse Knowledge Assessment" at the start of the course and a "Postcourse Knowledge Assessment" and a "Postcourse Student Perceptions Survey" at the end of the course. The primary end point, a comparison of course grades (%) between the main and distance campuses, was examined using the two-sample t-test. We examined the relationships among demographics, campus location, course grades, grade point average, pre- and postcourse knowledge assessments, and postcourse perceptions as our secondary end points with parametric and nonparametric tests. Data from 93 students were included in the analysis [main campus ( n = 81); distance campus ( n = 12)]. Students on the main campus achieved a significantly higher final course grade (87 vs. 81%; P = 0.02). Scores on the Postcourse Knowledge Assessment were also significantly higher compared with those of students on the distance education campus (77 vs. 68%; P = 0.04). Students on both campuses reported self-perceived improvement in their knowledge base regarding various aspects of infectious diseases. Compared with the students on the distance campus, those on the main campus were more likely to subjectively perceive that they had succeeded in the course ( P = 0.04). Our study suggests that students on the main campus achieved a higher final course grade and were more likely to feel that they had succeeded in the course. Students on both campuses reported improvement in knowledge.

[Digital learning and teaching in medical education : Already there or still at the beginning?] / Digitale Lehr- und Lernangebote in der medizinischen Ausbildung : Schon am Ziel oder noch am Anfang?

The current choice of digital teaching and learning formats in medicine is very heterogeneous. In addition to the widely used classical static formats, social communication tools, audio/video-based media, interactive formats, and electronic testing systems enrich the learning environment.For medical students, the private use of digital media is not necessarily linked to their meaningful use in the study. Many gain their experience of digital learning in the sense of "assessment drives learning", especially by taking online exams in a passive, consuming role. About half of all medical students can be referred to as "e-examinees" whose handling of digital learning is primarily focused on online exam preparation. Essentially, they do not actively influence their digital environment. Only a quarter can be identified as a "digital all-rounder", who compiles their individual learning portfolio from the broad range of digital media.At present, the use of digital media is not yet an integral and comprehensive component of the teaching framework of medical studies in Germany, but is rather used in the sense of a punctual teaching enrichment. Current trends in digital teaching and learning offerings are mobile, interactive, and personalized platforms as well as increasing the relevance of learning platforms. Furthermore, didactical concepts targeting the changed learning habits of the students are more successful regarding the acceptance and learning outcomes. In addition, digitalization is currently gaining importance as a component in the medical school curricula.

Arthroscopic Training in the 21st Century: A Changing Paradigm.

Although proficiency training will never completely replace the apprenticeship model, improvement in arthroscopic surgical-simulator technology permits students to spend less time observing and more time doing. The best models and simulators allow measurement and documentation of skill-based progression. Once basic skills have been satisfactorily demonstrated, trainees transitioning to actual operative arthroscopy should be expected to contribute to safer and more efficient patient care while continuing to learn and improve.

"Yes, and " Exploring the Future of Learning Analytics in Medical Education.

This Conversations Starter article presents a selected research abstract from the 2017 Association of American Medical Colleges Northeastern Region Group on Educational Affairs annual spring meeting. The abstract is paired with the integrative commentary of three experts who shared their thoughts stimulated by the study. Commentators brainstormed "what's next" with learning analytics in medical education, including advancements in interaction metrics and the use of interactivity analysis to deepen understanding of perceptual, cognitive, and social learning and transfer processes.

Emergent is Authentic: A Sociomaterial Perspective on Simulation-Enhanced Interprofessional Education.

This Conversations Starter article presents a selected research abstract from the 2017 Association of American Medical Colleges Western Region Group on Educational Affairs annual spring meeting. The abstract is paired with the integrative commentary of three experts who shared their thoughts stimulated by the study. The commentary explores the implications of sociomaterial perspectives for conceptualizing authenticity in the design and evaluation of simulation-enhanced interprofessional education.

Enhancement of Cricothyroidotomy Education Using a Novel Technique: Cadaver Autografting.

BACKGROUND: Cricothyroidotomy is a lifesaving procedure required in up to 2% of emergent airways. Emergency medicine training programs frequently instruct this procedure via cadaver training, but cadaver cost and availability limit the opportunity for all trainees to perform the critical initial skin incision. Cadaver autografting is a novel way to simulate all steps of the procedure. OBJECTIVE: Our aim was to determine whether the technique of autografting cadaver tissue improves the experience of cricothyroidotomy simulation education for emergency medicine trainees. The investigators hypothesized that autografted cadaver tissue would be a useful adjunct. METHODS: In this prospective crossover study, volunteers were randomized to first perform cricothyroidotomy on previously incised native neck tissue or on autografted tissue, and then vice versa. The autograft consisted of cadaver iliotibial band covered with lateral thigh skin and subcutaneous tissue to simulate cricothyroid membrane and native anterior neck anatomy. Volunteer emergency medicine residents and sub-interns were included. Twenty-seven residents and nine students participated. Outcomes were evaluated via Likert scale. RESULTS: Thirty of 36 (83%) participants agreed or strongly agreed that they preferred cadaver autografting to the previously incised native tissue. Thirty-two of 36 (89%) agreed or strongly agreed that cadaver autografting was useful vs. 23 of 36 (64%) who answered similarly regarding previously incised native tissue (p = 0.001). Twenty-six of 36 (72%) were more comfortable with cricothyroidotomy in the emergency department after using cadaver autografting vs. 19 of 36 (53%) after using the native tissue (p = 0.003). CONCLUSIONS: Autografted cadaver tissue while simulating cricothyroidotomy was perceived to be a useful adjunct by the majority of participating emergency medicine trainees.

Virtual Reality Educational Tool for Human Anatomy.

Virtual Reality is becoming widespread in our society within very different areas, from industry to entertainment. It has many advantages in education as well, since it allows visualizing almost any object or going anywhere in a unique way. We will be focusing on medical education, and more specifically anatomy, where its use is especially interesting because it allows studying any structure of the human body by placing the user inside each one. By allowing virtual immersion in a body structure such as the interior of the cranium, stereoscopic vision goggles make these innovative teaching technologies a powerful tool for training in all areas of health sciences. The aim of this study is to illustrate the teaching potential of applying Virtual Reality in the field of human anatomy, where it can be used as a tool for education in medicine. A Virtual Reality Software was developed as an educational tool. This technological procedure is based entirely on software which will run in stereoscopic goggles to give users the sensation of being in a virtual environment, clearly showing the different bones and foramina which make up the cranium, and accompanied by audio explanations. Throughout the results the structure of the cranium is described in detailed from both inside and out. Importance of an exhaustive morphological knowledge of cranial fossae is further discussed. Application for the design of microsurgery is also commented.

Recent advances of simulation in obstetric anesthesia.

PURPOSE OF REVIEW: Simulation training in obstetric anesthesia has become widespread in recent years. Simulations are used to train staff and trainees, assess and improve team performance, and evaluate the work environment. This review summarizes current research in these categories. RECENT FINDINGS: Simulation to improve individual technical skills has focused on induction of general anesthesia for emergent cesarean delivery, an infrequently encountered scenario by anesthesia trainees. Low- and high-fidelity simulation devices for the learning and practicing neuraxial and non-neuraxial procedures have been described, and both are equally effective. The use of checklists in obstetric emergencies has become common as and post-scenario debriefing techniques have improved. Although participant task performance improves, whether participants retain learned skills or whether simulation improves patient outcomes has not yet been established. Tools to assess teamwork during simulation have been developed, but none have been rigorously validated. In-situ vs. offsite simulations do not differ in effectiveness. SUMMARY: Simulation allows for practice of tasks and teamwork in a controlled manner. There is little data whether simulation improves patient outcomes and metrics to predict the long-term retention of skills by simulation participants have not been developed.