Student learning outcomes from a pilot medical innovations course with nursing, engineering, and biology undergraduate students
Background Preparing today’s undergraduate students from science, technology, engineering, and math (STEM) and related health professions to solve wide-sweeping healthcare challenges is critical. Moreover, it is imperative that educators help students develop the capabilities needed to meet those ch...
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Veröffentlicht in: | International journal of STEM education 2017-01, Vol.4 (1), p.33-14, Article 33 |
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Sprache: | eng |
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Zusammenfassung: | Background
Preparing today’s undergraduate students from science, technology, engineering, and math (STEM) and related health professions to solve wide-sweeping healthcare challenges is critical. Moreover, it is imperative that educators help students develop the capabilities needed to meet those challenges, including problem solving, collaboration, and an ability to work with rapidly evolving technologies. We piloted a multidisciplinary education (ME) course aimed at filling this gap, and subsequently assessed whether or not students identified achieving the course objectives. In the course, undergraduate students from engineering, pre-nursing (students not yet admitted to the nursing program), and pre-professional health (e.g., pre-med and pre-physician’s assistant) were grouped based on their diversity of background, major, and StrengthsFinder® proficiencies in a MakerSpace to create tangible solutions to health-related problems facing the community. We then used qualitative content analysis to assess the research question: what is the impact of undergraduate multidisciplinary education offered in a MakerSpace on student attitudes towards and perceptions of skills required in their own as well as others occupations?
Results
We discovered these students were able to identify and learn capabilities that will be critical in their future work. For example, students appreciated the challenging problems they encountered and the ability to meet demands using cutting-edge technologies including 3D printers. Moreover, they learned the value of working in a multidisciplinary group. We expected some of these findings, such as an increased ability to work in teams. However, some themes were unexpected, including students explicitly appreciating the method of teaching that focused on experiential student learning through faculty mentoring.
Conclusions
These findings can be used to guide additional research. Moreover, offering a variety of these courses is a necessary step to prepare students for the current and future workforce. Finally, these classes should include a focus on intentional team creation with the goal of allowing students to solve challenging real-world problems through ethical reasoning and collaboration. |
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ISSN: | 2196-7822 2196-7822 |
DOI: | 10.1186/s40594-017-0095-y |