The RASOR project is designed to increase engagement of students from rural Alaska communities in biomedical/STEM careers. Rural Alaskan communities are home to students of intersecting identities underrepresented in biomedical science, including Alaska Native, low-income, first generation college, and rural. Geographic isolation defines these communities and can limit the exposure of students to scientifically-minded peers, professional role models, and science career pathways. However these students also have a particularly strong environmental connection through subsistence and recreational activities, which makes the one-health approach to bio-medicine an intuitive and effective route for introducing scientific research and STEM content. In RASOR, we will implement place-based mentored research projects with students in rural Alaskan communities at the high school level, when most students are beginning to seriously consider career paths. The biomedical one-health approach will build connections between student experiences of village life in rural Alaska and biomedical research. Engaging undergraduate students in research has proved one of the most successful means of increasing the persistence of minority students in science (Kuh 2008). Furthermore, RASOR will integrate high school students into community-based participatory research (Israel et al. 2005). This approach is designed to demonstrate the practicality of scientific research, that science has the ability to support community and cultural priorities and to provide career pathways for individual community members. The one-health approach will provide continuity with BLaST, an NIH-funded BUILD program that provides undergraduate biomedical students with guidance and support. RASOR will work closely with BLaST, implementing among younger (pre-BLaST) students approaches that have been successful for retaining rural Alaska students along STEM pathways and tracking of post-RASOR students. Alaska Native and rural Alaska students are a unique and diverse population underrepresented in biomedical science and STEM fields.
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TEAM MEMBERS:
Janice StraleyEllen Chenowith
resourceresearchGames, Simulations, and Interactives
We describe a game and teachers’ experiences using it in their middle and high school science courses. The game, which is called “Luck of the Draw,” was designed to engage middle, high school, and college students in genetics and encourage critical thinking about issues, such as genetic engineering. We introduced the game to high school science teachers attending a summer workshop and asked them to describe their initial impressions of the game and how they might use it in their classes; later, during the academic year, we asked them whether they used the game in their classrooms and, if so
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TEAM MEMBERS:
Alicia BowerKami L. TsaiCarey S. RyanRebecca AndersonAndrew JametonMaurice Godfrey
This is the final report from the external evaluator of the project that created MedLab, an interactive learning experiences for Chicago area middle and high school students. This external evaluator's final report summarizes the outcomes and impacts of the five-year (2012-2017) funding compared to project objectives. The aim of the project was to use in person and online curricula, including a humanoid patient simulator (iStan®), to build interest in and knowledge of health sciences and health careers, with a particular focus on local community health concerns. An additional goal was to
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TEAM MEMBERS:
Christina Shane-SimpsonJohn FraserSusan HannahKin KongPatricia WardRabiah Mayas
There is broad consensus in the international scientific community that the world is facing a biodiversity crisis — the accelerated loss of life on Earth brought about by human activity. Threats to biodiversity have been variously classified by different authors (Diamond 1989, Laverty and Sterling 2004, Brook et al. 2008), but typically include ecosystem loss and fragmentation, unsustainable use, invasive species, pollution, and climate change. Across the globe, traditional and indigenous cultures are affected by many of the same threats affecting biological diversity, including the
Brazilian research has grown intensely in all areas of microbiology, with the increase in the amount of governmental resources for the sector and the strengthening of a greater number of research groups. However, very few academic studies deal with research about teaching and science communication in microbiology. There is no in-depth study of how this topic is currently being divulgated in communication journals, didactic books and the Internet, or about the interest and the difficulties faced by researchers in communicating microbiology to the general public. This paper investigates academic
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TEAM MEMBERS:
Daniela Franco Carvalho JacobucciGiuliano Buza Jacobucci
The connections among neuroscience, educational research, and teaching practice have historically been tenuous (Cameron and Chudler 2003; Devonshire and Dommett 2010). This is particularly true in public schools, where so many issues are competing for attention—state testing, school politics, financial constraints, lack of time, and demands from parents and the surrounding community. Teachers and administrators often struggle to make use of advances in educational research to impact teaching and learning (Hardiman and Denckla 2009; Devonshire and Dommett 2010). At the Franklin Institute, we
This report highlights advances in neuroscience with potential implications for education and lifelong learning. The report authors, including neuroscientists, cognitive psychologists and education specialists, agree that if applied properly, the impacts of neuroscience could be highly beneficial in schools and beyond. The report argues that our growing understanding of how we learn should play a much greater role in education policy and should also feature in teacher training. The report also discusses the challenges and limitations of applying neuroscience in the classroom and in learning
This report from the National Research Council explores how learning changes the physical structure of the brain, how existing knowledge affects what people notice and how they learn, the amazing learning potential of infants, and the relationship between classroom learning and learning in everyday settings such as community and the workplace. It identifies learning needs and opportunities for teachers and provides a realistic look at the role of technology in education.
In this review paper, Oliver calls for greater cross-pollination between neuroscience research and educational practice. She asks, “What can educators learn from an understanding of educational neuroscience?”
Elementary school children are capable of reproducing sophisticated science process skills such as observing, designing experiments, collecting data, and evaluating evidence. An understanding of the nature of scientific knowledge requires more than teaching and learning the performance of these skills. It also requires an appreciation of how these actions lead to knowledge generation and shape its durable and tentative nature. Our understanding of activities that support the teaching and learning of the nature of scientific knowledge is still growing. This study compares how scientific
Science Club is an after school program created in partnership between Northwestern University and the Boys & Girls Clubs of Chicago. Every week throughout the academic year, middle school youth (grades 5-8) work in small groups with their graduate student mentors on challenging, hands-on experiments. The six Science Club curricular modules cover topics ranging from biomedical engineering to food science, all with the goals of helping youth to 1) improve their understanding of the scientific method, 2) develop scientific habits of mind, and 3) increase their interest in STEM fields, particularly health-related careers. Science Club serves 60 youth every quarter with the help of 30 trained scientist mentors. Science Club meets three days a week at the Pedersen-McCormick Boys & Girls Club in Chicago, IL.
The article presents a lesson plan for eighth-grade students on neuromuscular control and biomedical engineering based on the engineering and design of prosthetic hands.
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TEAM MEMBERS:
Justin RyanDavid FrakesTirupalavanam GaneshChristine Zwart