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Simulation Technology (simulation + technology)

Distribution by Scientific Domains

Medical Sciences	88%

Selected Abstracts

Use of Simulation Technology in Forensic Medical Education

ACADEMIC EMERGENCY MEDICINE, Issue 2009
Heather Rozzi
Although the emergency department often provides the first and only opportunity to collect forensic evidence, very few emergency medicine residencies have a forensic medicine curriculum in place. Most of the existing curricula are composed only of traditional didactics. However, as with any lecture-based education, there may be a significant delay between the didactic session and clinical application. In addition, traditional curricula lack the opportunity for residents to practice skills including evidence collection, documentation, and use of a colposcope. At York Hospital, we have developed a forensic curriculum which consists of both traditional lectures and practical experience in our Medical Simulation Center. As part of their educational conference series, residents receive presentations on domestic violence, child abuse, elder abuse, evidence collection, sexual assault, ballistics, pattern injuries, documentation, forensic photography, and court testimony. Following these presentations, residents have the opportunity to apply their knowledge of forensic medicine in the Simulation Center. First, they interview a standardized patient. They then utilize the mannequins in the Simulation Center to practice evidence collection, photo documentation, and use of our specialized forensic medicine charts. After evidence collection and documentation, the residents provide safety planning for the standardized patients. Each portion is videotaped, and each resident is debriefed by victim advocates, experienced sexual assault nurse examiners, and emergency department faculty. The use of simulation technology in resident education provides the opportunity to practice the skills of forensic medicine, ultimately benefiting patients, residents, and law enforcement, and permitting teaching and evaluation in all six core competency areas. [source]

The Assessment of Individual Cognitive Expertise and Clinical Competency: A Research Agenda

ACADEMIC EMERGENCY MEDICINE, Issue 11 2008
Linda Spillane MD
Abstract There is a large push to utilize evidence-based practices in medical education. At the same time, credentialing bodies are evaluating the use of simulation technologies to assess the competency and safety of its practitioners. At the 2008 Academic Emergency Medicine Consensus Conference on "The Science of Simulation in Healthcare," our breakout session critically evaluated several issues important to the use of simulation in emergency physician (EP) assessment. In this article, we discuss five topics felt to be most critical to simulation-based assessment (SBA). We then offer more specific research questions that would help to define and implement a SBA program in emergency medicine (EM). [source]

Effect of augmented visual feedback from a virtual reality simulation system on manual dexterity training

EUROPEAN JOURNAL OF DENTAL EDUCATION, Issue 1 2005
E. Wierinck
Little research has been published about the impact of simulation technology on the learning process of novel motor skills. Especially the role of augmented feedback (FB) on the quality of performance and the transfer of the acquired behaviour to a no-augmented FB condition require further investigation. Therefore, novice dental students were randomly assigned to one of three groups and given the task of drilling a geometrical class 1 cavity. The FB group trained under augmented visual FB conditions, provided by the virtual reality (VR) system (DentSimTM). The no-FB group practised under normal vision conditions, in the absence of augmented FB. A control group performed the test sessions without participating in any training programme. All preparations were evaluated by the VR grading system according to four traditional (outline shape, floor depth, floor smoothness and wall inclination), and two critical, criteria (pulp exposure and damage to adjacent teeth). Performance analyses revealed an overall trend towards significant improvement with training for the experimental groups. The FB group obtained the highest scores. It scored better for floor depth (P < 0.001), whilst the no-FB group was best for floor smoothness (P < 0.005). However, at the retention tests, the FB group demonstrated inferior performance in comparison with the no-FB group. The transfer test on a traditional unit revealed no significant differences between the training groups. Consequently, drilling experience on a VR system under the condition of frequently provided FB and lack of any tutorial input was considered to be not beneficial to learning. The present data are discussed in view of the guidance hypothesis of FB, which refers to the apprentice's dependence on FB. [source]

Companies rehearse a very different future: Connecting leadership capability and strategy execution through simulation

GLOBAL BUSINESS AND ORGANIZATIONAL EXCELLENCE, Issue 5 2009
Ron Carucci
How can an organization's leaders best learn the behaviors and competencies required in a very different future? "Rehearsing the future" simulations immerse leaders in a fictitious business context strategically similar to their company's desired future to solve critical issues as a leadership team. The author differentiates future rehearsal simulation from computer simulation; describes when, where, and why these simulations are effective; and details the process for building a simulation that integrates multiple leadership development tools. Two actual cases, a global technology corporation seeking a horizontally integrated platform of products and services and a biotech company determined to shorten its product development timelines, illustrate the benefits of simulation technology for leaders and the business. © 2009 Wiley Periodicals, Inc. [source]

New horizons in simulation training for endoscopic surgery

ASIAN JOURNAL OF ENDOSCOPIC SURGERY, Issue 1 2010
D. King
Abstract In recent years there has been both a paradigm shift in the way surgery is carried out and also in the way in which we train health professionals undertaking interventional procedures. Endoscopic procedures have replaced many traditional operations and the benefits of such an approach to patient care are well documented. However, evidence exists of higher patient complications during a surgeon's learning curve in endoscopic surgery, and it is now considered essential that endoscopic skills are learned in training laboratories rather than on patients. A new model of structured education, where surgical skills are practiced on models and virtual reality simulators, is set to replace the traditional apprenticeship model of training. Simulation is a rapidly evolving field that can provide a safe and increasingly realistic learning environment for trainees to practice in. This paper explores the current role of simulation in endoscopic training and provides a review of the developments in the field, including advances in simulation technology, progress in curriculum design and the use of simulation in nontechnical skills training. [source]

Use of Simulation Technology in Forensic Medical Education

Summative Assessment in Medicine: The Promise of Simulation for High-stakes Evaluation

ACADEMIC EMERGENCY MEDICINE, Issue 11 2008
John R. Boulet PhD
Abstract Throughout their careers, physicians are exposed to a wide array of assessments, including those aimed at evaluating knowledge, clinical skills, and clinical decision-making. While many of these assessments are used as part of formative evaluation activities, others are employed to establish competence and, as a byproduct, to promote patient safety. In the past 10 years, simulations have been successfully incorporated in a number of high-stakes physician certification and licensure exams. In developing these simulation-based assessments, testing organizations were able to promote novel test administration protocols, build enhanced assessment rubrics, advance sophisticated scoring and equating algorithms, and promote innovative standard-setting methods. Moreover, numerous studies have been conducted to identify potential threats to the validity of test score interpretations. As simulation technology expands and new simulators are invented, this groundbreaking work can serve as a basis for organizations to build or expand their summative assessment activities. Although there will continue to be logistical and psychometric problems, many of which will be specialty- or simulator-specific, past experience with performance-based assessments suggests that most challenges can be addressed through focused research. Simulation, whether it involves standardized patients (SPs), computerized case management scenarios, part-task trainers, electromechanical mannequins, or a combination of these methods, holds great promise for high-stakes assessment. [source]

Developing Expert Medical Teams: Toward an Evidence-based Approach

ACADEMIC EMERGENCY MEDICINE, Issue 11 2008
Rosemarie Fernandez MD
Abstract Current health care literature cites communication breakdown and teamwork failures as primary threats to patient safety. The unique, dynamic environment of the emergency department (ED) and the complexity of patient care necessitate the development of strong interdisciplinary team skills among emergency personnel. As part of the 2008 Academic Emergency Medicine Consensus Conference on "The Science of Simulation in Healthcare," our workshop group identified key theory and evidence-based recommendations for the design and implementation of team training programs. The authors then conducted an extensive review of the team training literature within the domains of organizational psychology, aviation, military, management, and health care. This review, in combination with the workshop session, formed the basis for recommendations and need for further research in six key areas: 1) developing and refining core competencies for emergency medicine (EM) teams; 2) leadership training for emergency physicians (EPs); 3) conducting comprehensive needs analyses at the organizational, personnel, and task levels; 4) development of training platforms to maximize knowledge transfer; 5) debriefing and provision of feedback; and 6) proper implementation of simulation technology. The authors believe that these six areas should form an EM team training research platform to advance the EM literature, while leveraging the unique team structures present in EM to expand team training theory and research. [source]

The Emergency Physician and Knowledge Transfer: Continuing Medical Education, Continuing Professional Development, and Self-improvement

ACADEMIC EMERGENCY MEDICINE, Issue 11 2007
Barbara J. Kilian MD
A workshop session from the 2007 Academic Emergency Medicine Consensus Conference, Knowledge Translation in Emergency Medicine: Establishing a Research Agenda and Guide Map for Evidence Uptake, focused on developing a research agenda for continuing medical education (CME) in knowledge transfer. Based on quasi-Delphi methodology at the conference session, and subsequent electronic discussion and refinement, the following recommendations are made: 1) Adaptable tools should be developed, validated, and psychometrically tested for needs assessment. 2) "Point of care" learning within a clinical context should be evaluated as a tool for practice changes and improved knowledge transfer. 3) The addition of a CME component to technological platforms, such as search engines and databases, simulation technology, and clinical decision-support systems, may help knowledge transfer for clinicians or increase utilization of these tools and should, therefore, be evaluated. 4) Further research should focus on identifying the appropriate outcomes for physician CME. Emergency medicine researchers should transition from previous media-comparison research agendas to a more rigorous qualitative focus that takes into account needs assessment, instructional design, implementation, provider change, and care change. 5) In the setting of continued physician learning, barriers to the subsequent implementation of knowledge transfer and behavioral changes of physicians should be elicited through research. [source]