Instructional-design framework that supports goals, values, and systematic methods has been shown to overcome the shortcomings of a technology-driven approach, which traditionally has been used to design technology-enhanced training programs [6]. However, in our comprehensive literature search, we did not find a published design framework that guides the design and development of AR in health care education. The spread of Pristinamycin IA web antibiotic resistance has become a major threat to global public health [7]. A health systems perspective was suggested to solve the dangers and ethical dilemmas of current use, misuse, and overuse of antibiotics [8]. General practitioners (GPs) are an essential part of medical care throughout the world, and their education in rational antibiotic use should enhance care in higher-income and lower-income settings [9]. Evidence shows that the effects of GP training in appropriate antibiotic use varies [10]. Well-designed medical education has been shown to improve targeted antibiotic prescribing outcomes [11]. However, evidence also shows that educational outreach often fails in more experimental settings due to CBR-5884 manufacturer insufficient workability where the education does not “fit” with the work environment [12]. In addition, drug-centered pharmacology teaching or disease-centered diagnostic clinical training has been weak in transforming pharmacological knowledge into clinical practice [13]. To address this health care education challenge, our study examined the use of augmented reality as a powerful partner to bridge the gap between knowledge and practice. Mobile technology, which is portable and can be easily immersed in different environments, is developing rapidly. According to a report by Morgan Stanley, by 2020 the use of mobile Internet computing is projected to surpass desktop Internet usage by over 10 times [14]. There are currently more than 100,000 health care apps available [15], and current mobile tools–tablets, mobile phones, and other wearable devices–include features that rival existing AR tools (eg, built-in video cameras, global positioning systems [GPS], wireless receivers, and sensors) [16]. This integration of embedded devices can facilitate the ability to track learners in their natural environment and objects that enhance learning [17]. In health education, app-based mobile devices have been shown to support individual and social aspects of learning [18].JMIR Medical Education 2015 | vol. 1 | iss. 2 | e10 | p.2 (page number not for citation purposes)2. 3.AR provides users with an authentic and situated experience, when connected with the surrounding real-world environment. AR enhances the physical environment around users with virtual information that becomes interactive and digital. AR shows users an indirect view of their surroundings and enhances users’ senses through virtual information.When companies were developing early versions of AR, an important focus area was workplace training. Within health care education, AR has been used across a range of subject areas. In our preintegrative review of papers published before November 2012 [4], we identified 2529 research papers in the Education Resources Information Center (ERIC), the Cumulative Index to Nursing and Allied Health Literature (CINAHL), MEDLINE, Web of Science, PubMed, and SpringerLink through computerized searching with two groups of words: augmented reality and its synonyms, and medical education and its synonyms. A total of 439 full papers w.Instructional-design framework that supports goals, values, and systematic methods has been shown to overcome the shortcomings of a technology-driven approach, which traditionally has been used to design technology-enhanced training programs [6]. However, in our comprehensive literature search, we did not find a published design framework that guides the design and development of AR in health care education. The spread of antibiotic resistance has become a major threat to global public health [7]. A health systems perspective was suggested to solve the dangers and ethical dilemmas of current use, misuse, and overuse of antibiotics [8]. General practitioners (GPs) are an essential part of medical care throughout the world, and their education in rational antibiotic use should enhance care in higher-income and lower-income settings [9]. Evidence shows that the effects of GP training in appropriate antibiotic use varies [10]. Well-designed medical education has been shown to improve targeted antibiotic prescribing outcomes [11]. However, evidence also shows that educational outreach often fails in more experimental settings due to insufficient workability where the education does not “fit” with the work environment [12]. In addition, drug-centered pharmacology teaching or disease-centered diagnostic clinical training has been weak in transforming pharmacological knowledge into clinical practice [13]. To address this health care education challenge, our study examined the use of augmented reality as a powerful partner to bridge the gap between knowledge and practice. Mobile technology, which is portable and can be easily immersed in different environments, is developing rapidly. According to a report by Morgan Stanley, by 2020 the use of mobile Internet computing is projected to surpass desktop Internet usage by over 10 times [14]. There are currently more than 100,000 health care apps available [15], and current mobile tools–tablets, mobile phones, and other wearable devices–include features that rival existing AR tools (eg, built-in video cameras, global positioning systems [GPS], wireless receivers, and sensors) [16]. This integration of embedded devices can facilitate the ability to track learners in their natural environment and objects that enhance learning [17]. In health education, app-based mobile devices have been shown to support individual and social aspects of learning [18].JMIR Medical Education 2015 | vol. 1 | iss. 2 | e10 | p.2 (page number not for citation purposes)2. 3.AR provides users with an authentic and situated experience, when connected with the surrounding real-world environment. AR enhances the physical environment around users with virtual information that becomes interactive and digital. AR shows users an indirect view of their surroundings and enhances users’ senses through virtual information.When companies were developing early versions of AR, an important focus area was workplace training. Within health care education, AR has been used across a range of subject areas. In our preintegrative review of papers published before November 2012 [4], we identified 2529 research papers in the Education Resources Information Center (ERIC), the Cumulative Index to Nursing and Allied Health Literature (CINAHL), MEDLINE, Web of Science, PubMed, and SpringerLink through computerized searching with two groups of words: augmented reality and its synonyms, and medical education and its synonyms. A total of 439 full papers w.
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