Pocket Book for Simulation Debriefing in Healthcare

© 2018 Springer International Publishing AG. This is a post-peer-review, pre-copyedit sample portion of 'Pocket Book for Simulation Debriefing in Healthcare'. The final authenticated version is available online at: http://dx.doi.org/10.1007/978-3-319-59882-6This book is a concise manual on debriefing techniques in a clinical educational context. It presents the most popular debriefing techniques and, hence, can be used as a reference manual by educators to help them achieve their intended debriefing objectives. The overarching objective of debriefing is to promote reflection and improve patient safety awareness at an individual and a team level. This book provides clear explanations of what constitutes a valuable and effective debriefing, and presents the various approaches that can be used and how debriefing differs from feedback. It includes key recommendations on aspects that directly or indirectly impact debriefing with different populations of learners such as students or qualified healthcare professionals of various levels of seniority. This book can also be used as a survival guide for both simulation educators and clinicians during debriefings. It includes several useful sections explaining the different phases of a debriefing session, which help learners develop and consolidate their knowledge, and identify potential knowledge or performance gaps and near misses. The underlying philosophy of this book is to also promote profound respect for the trainee by using a non-offensive debriefing approach. Debriefing facilitators will appreciate the several key sentences that will help them lead and engage their learners in the various phases of expressing their emotions and analyzing their experience and actions

Twelve tips for rapidly migrating to online learning during the COVID-19 pandemic

The COVID-19 pandemic has resulted in a massive adaptation in health professions education, with a shift from in-person learning activities to a sudden heavy reliance on internet-mediated education. Some health professions schools will have already had considerable educational technology and cultural infrastructure in place, making such a shift more of a different emphasis in provision. For others, this shift will have been a considerable dislocation for both educators and learners in the provision of education. To aid educators make this shift effectively, this 12 Tips article presents a compendium of key principles and practical recommendations that apply to the modalities that make up online learning. The emphasis is on design features that can be rapidly implemented and optimised for the current pandemic. Where applicable, we have pointed out how these short-term shifts can also be beneficial for the long-term integration of educational technology into the organisations' infrastructure. The need for adaptability on the part of educators and learners is an important over-arching theme. By demonstrating these core values of the health professions school in a time of crisis, the manner in which the shift to online learning is carried out sends its own important message to novice health professionals who are in the process of developing their professional identities as learners and as clinicians

Ecodriving and Carbon Footprinting: Understanding How Public Education Can Reduce Greenhouse Gas Emissions and Fuel Use

Ecodriving is a collection of changes to driving behavior and vehicle maintenance designed to impact fuel consumption and greenhouse gas (GHG) emissions in existing vehicles. Because of its promise to improve fuel economy within the existing fleet, ecodriving has gained increased attention in North America. One strategy to improve ecodriving is through public education with information on how to ecodrive. This report provides a review and study of ecodriving from several angles. The report offers a literature review of previous work and programs in ecodriving across the world. In addition, researchers completed interviews with experts in the field of public relations and public message campaigns to ascertain best practices for public campaigns. Further, the study also completed a set of focus groups evaluating consumer response to a series of websites that displayed ecodriving information. Finally, researchers conducted a set of surveys, including a controlled stated-response study conducted with approximately 100 University of California, Berkeley faculty, staff, and students, assessing the effectiveness of static ecodriving web-based information as well as an intercept clipboard survey in the San Francisco Bay Area. The stated-response study consisted of a comparison of the experimental and control groups. It found that exposure to ecodriving information influenced people’s driving behavior and some maintenance practices. The experimental group’s distributional shift was statistically significant, particularly for key practices including: lower highway cruising speed, driving behavior adjustment, and proper tire inflation. Within the experimental group (N = 51), fewer respondents significantly changed their maintenance practices (16%) than the majority that altered some driving practices (71%). This suggests intentionally altering driving behavior is easier than planning better maintenance practices. While it was evident that not everyone modifies their behavior as a result of reviewing the ecodriving website, even small shifts in behavior due to inexpensive information dissemination could be deemed cost effective in reducing fuel consumption and emissions

A domain-specific design architecture for composite material design and aircraft part redesign

Advanced composites have been targeted as a 'leapfrog' technology that would provide a unique global competitive position for U.S. industry. Composites are unique in the requirements for an integrated approach to designing, manufacturing, and marketing of products developed utilizing the new materials of construction. Numerous studies extending across the entire economic spectrum of the United States from aerospace to military to durable goods have identified composites as a 'key' technology. In general there have been two approaches to composite construction: build models of a given composite materials, then determine characteristics of the material via numerical simulation and empirical testing; and experience-directed construction of fabrication plans for building composites with given properties. The first route sets a goal to capture basic understanding of a device (the composite) by use of a rigorous mathematical model; the second attempts to capture the expertise about the process of fabricating a composite (to date) at a surface level typically expressed in a rule based system. From an AI perspective, these two research lines are attacking distinctly different problems, and both tracks have current limitations. The mathematical modeling approach has yielded a wealth of data but a large number of simplifying assumptions are needed to make numerical simulation tractable. Likewise, although surface level expertise about how to build a particular composite may yield important results, recent trends in the KBS area are towards augmenting surface level problem solving with deeper level knowledge. Many of the relative advantages of composites, e.g., the strength:weight ratio, is most prominent when the entire component is designed as a unitary piece. The bottleneck in undertaking such unitary design lies in the difficulty of the re-design task. Designing the fabrication protocols for a complex-shaped, thick section composite are currently very difficult. It is in fact this difficulty that our research will address

Mathematical modelling of angiogenesis and vascular adaptation

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I am not a superhero but I do have secret weapons! : using technology in higher education teaching to redress the power balance

This article explores the role of technology in supporting student learning. It expresses the view that university/college students need to have educators who act as 'superheroes' seeking to understand their students' views of the world and their learning experiences within it. The author explores how a range of 'secret weapons' namely learning and communication technologies have been used by a reluctant adopter (not a superhero) to simply and effectively engage and empower students in the classroom. The overall aim of this approach was to offer students an opportunity to learn in a way that will put them in a strong position to be successful not only at university but also in their life ahead. Beginning with a discussion of the current UK learning context and the power dynamics that exist within the university classroom, the article then goes on to offer practical and pragmatic advice on using a specific range of technologies to support student learning. These technologies are a student response system called Socrative (available as a free smartphone app); Google Sites (a free website building tool - used for enhancing case studies and designing authentic assessments); tablet computers and audio (voice) feedback recorders. The paper concludes with a range of general tips for those adopting new technologies. These include involving the wider team (fellow academics and learning technologists) as well as students. Additionally it encourages thinking about pedagogical and practical approaches that need to be considered when adopting new technology either in the classroom or in assessment

Physical simulation for monocular 3D model based tracking

The problem of model-based object tracking in three dimensions is addressed. Most previous work on tracking assumes simple motion models, and consequently tracking typically fails in a variety of situations. Our insight is that incorporating physics models of object behaviour improves tracking performance in these cases. In particular it allows us to handle tracking in the face of rigid body interactions where there is also occlusion and fast object motion. We show how to incorporate rigid body physics simulation into a particle filter. We present two methods for this based on pose and force noise. The improvements are tested on four videos of a robot pushing an object, and results indicate that our approach performs considerably better than a plain particle filter tracker, with the force noise method producing the best results over the range of test videos