For nearly 20 years, the UAB Center for Community OutReach Development (CORD) has conducted SEPA funded research that has greatly enhanced the number of minority students entering the pipeline to college and biomedical careers, e.g., nearly all of CORD’s Summer Research Interns since 1998 (>300) have completed/are completing college and most of them are continuing on to graduate biomedical research and/or clinical training and careers. CORD’s programs that focused on high and middle school students have drawn many minority students into biomedical careers, but a low percentage of minority students benefit from these programs because far too many are already left behind academically in grades 4-6, due, at least in part, to a significant drop in science grades between grades 4 and 6, a drop from which most students never recover. A major contributor to this effect is that most grade 4-6 teachers in predominantly minority schools lack significant formal training in science and often are not fully aware of the great opportunities offered by biomedical careers.
In SEEC II, CORD will deliver intensive inquiry-based science training to grade 4-6 teachers, providing them with science content and hands-on science experiences that will afford their student both content and skills that will make them excited about, and competitive for, the advanced courses needed to move into biomedical research careers. SEEC II will also link teachers together across the elementary/middle school divide and bring the teachers together with administrators and parents, who will experience firsthand the excitement that inquiry learning brings and the significant advancement it provides in science and in reading and math. At monthly meetings and large annual celebrations, the parents, teachers and administrators will learn about the opportunities that biomedical careers can provide for the student who is well prepared. They will also consider the financial and educational steps required to ensure that students have the ability to reach these professions.
SEEC II will also expand CORD’s middle school LabWorks and Summer Science Camps to include grade 4-5 students and provide the teachers with professional learning in informal settings. During summer training, in small groups, the teachers will expand one of the inquiry-based science activities that they complete in the training, and they will use these in their classrooms and communicate with the others in their group to perfect these experiences in the school year. Finally, the teachers and grade 4-5 students will develop science and engineering fair-type research projects with which they will compete both on the school level and at the annual meeting. Thus, the students will share with their parents the excitement that science brings. The Intellectual Merit of SEEC II will be to test a model to enhance grade 4-6 teacher development and vertical alignment, providing science content, exposure to biomedical scientists and training in participatory science experiments, thus positioning teachers to succeed. The Broader Impacts will include the translation and testing of a science education model to assist minority students to avoid the middle school plunge and reach biomedical careers.
The employment demands in STEM fields grew twice as fast as employment in non-STEM fields in the last decade, making it a matter of national importance to educate the next generation about science, engineering and the scientific process. The need to educate students about STEM is particularly pronounced in low-income, rural communities where: i) students may perceive that STEM learning has little relevance to their lives; ii) there are little, if any, STEM-related resources and infrastructure available at their schools or in their immediate areas; and iii) STEM teachers, usually one per school, often teach out of their area expertise, and lack a network from which they can learn and with which they can share experiences. Through the proposed project, middle school teachers in low-income, rural communities will partner with Dartmouth faculty and graduate students and professional science educators at the Montshire Museum of Science to develop sustainable STEM curricular units for their schools. These crosscutting units will include a series of hands-on, investigative, active learning, and standards-aligned lessons based in part on engineering design principles that may be used annually for the betterment of student learning. Once developed and tested in a classroom setting in our four pilot schools, the units will be made available to other partner schools in NH and VT and finally to any school wishing to adopt them. In addition, A STEM rural educator network, through which crosscutting units may be disseminated and teachers may share and support each other, will be created to enhance the teachers’ ability to network, seek advice, share information, etc.
Biology has become a powerful and revolutionary technology, uniquely poised to transform and propel innovation in the near future. The skills, tools, and implications of using living systems to engineer innovative solutions to human health and global challenges, however, are still largely foreign and inaccessible to the general public. The life sciences need new ways of effectively engaging diverse audiences in these complex and powerful fields. Bio-Tinkering Playground will leverage a longtime partnership between the Stanford University Department of Genetics and The Tech Museum of Innovation to explore and develop one such powerful new approach.
The objective of Bio-Tinkering Playground is to create and test a groundbreaking type of museum space: a DIY community biology lab and bio-makerspace, complete with a unique repertoire of hands-on experiences. We will tackle the challenge of developing both open-ended bio-making activities and more scaffolded ones that, together, start to do for biology, biotech, and living systems what today’s makerspaces have done for engineering.
A combined Design Challenge Learning, making, and tinkering approach was chosen because of its demonstrated effectiveness at fostering confidence, creative capacity, and problem solving skills as well as engaging participants of diverse backgrounds. This educational model can potentially better keep pace with the emerging and quickly evolving landscape of biotech to better prepare young people for STEM careers and build the next generation of biotech and biomedical innovators.
Experience development will be conducted using an iterative design process that incorporates prototyping and formative evaluation to land on a final cohort of novel, highly-vetted Bio-Tinkering Playground experience. In the end, the project will generate a wealth of resources and learnings to share with the broader science education field. Thus, the impacts of our foundational work can extend well beyond the walls of The Tech as we enable other educators and public institutions around the world to replicate our model for engagement with biology.
Bio Med Tech: Engineering for Your Health was a 2,750 square foot exhibition at the Great Lakes Science Center (GLSC) that dealt with issues related to biomedical technology. Partially funded by a grant from the National Institutes of Health Science Education Partnership Awards program (NIH/SEPA), the project was developed through a partnership between GLSC and Case Western Reserve University. The SEPA grant also funded a variety of programming activities, including informal Exploration Cart activities in the exhibition, presentations in the exhibition's theater space, and teacher training
The Nanomedicine Explorer kiosk at the Museum of Science, Boston provides opportunities to learn about nanomedicine, nanotechnology, cancer biology, new research in cancer diagnosis and therapy, and the process of medical research from bench to bedside. This report is the formative evaluation of the prototype of this kiosk, presenting the results of visitor observations, exit surveys, and interviews. The findings of these data served to provide the Nanomedicine Explorer production team a basis from which to make improvements to the program, which was released as Version 1.0 in May of 2009
The investigators address a major educational challenge by introducing a novel format and content for science education, (a) building on past successes; (b) combining development and dissemination at a new level; and (c) centered around an interactive planetarium show aimed to inform the public on an emerging scientific discipline and medical field: Tissue Engineering. For achieving a multitude of goals, the investigators propose the establishment of a unique partnership in scientific and medical education, bringing together university researchers, clinical leaders, science center experts, and students, educators and community representatives at all levels. The project is catalyzed by the Pittsburgh Tissue Engineering Initiative, a non-profit organization dedicated to the promotion of tissue engineering and its application to improving people's lives. The main goals fall in three categories, as follows: Education: - To communicate scientific information about the human body (principles of function will be emphasized over specific facts or terminology by focusing on a limited but fundamental set). -To convey the excitement and importance of tissue engineering research. The show will utilize engaging interactive demonstrations of tissue functions and illustrate the medical uses and potential of this field. Innovation: - To enhance the educational experience. The developers will use group-interactive technology as a tool for education by engaging participants as participants in the processing functions of the body. A special visualization/interactivity laboratory will be used where prototype interactive scenarios will be tested using focus groups, consultants and representatives of the target audiences. Dissemination: - To insure national distribution to other planetaria. The presentation system will utilize portable interactive technology (to be developed). It will be deployed to planetaria throughout the country, coordinated by the Association of Science and Techology Centers (ASTC). - To engage the target audience in the development process. Content development will be achieved by a consortium of leading research universities and medical centers, with input from a panel of worldclass experts. Visualization, interactivity and sound technologies will be developed in Pittsburgh, in a unique collaboration between the arts and sciences, based on past successes. Evaluation activities will be extensive, as will the range and targets of the spin-off educational materials. The Carnegie Science Center planetarium itself will serve in achieving group immersive visualization, akin to virtual reality, for improving target audience involvement. The expected outcome is a new way of delivering educational content, and a better understanding of the emerging field of tissue engineering by the general public.
The Great Lakes Science Center, in collaboration with Case Western Reserve University (CASE), proposes to develop a permanent exhibition and related programs on biomedical engineering. The successful implementation of this project would allow CASE and GLSC to inform a broad constituency about select biomedical research advancements, applied technologies, and their relevance to society. When the project is completed, we will be able to expose many thousands of visitors each year to the updated exhibition - increasing their interest in and understanding of important science concepts underlying advancements in biomedical technology. The exhibition would encompass approximately 2000 square feet and feature approximately 20 exhibits, most of which would be interactive. The major audiences for the exhibition include families, school groups, and general museum visitors. The BioMedTech exhibition is located on the Science Center's main floor, which places an emphasis on the science and technology of particular importance to Northeast Ohio. The exhibition will be accompanied by educational programming, public programs, and wide dissemination around the region and within the Science Center world. When fully implemented, the project could reach many hundreds of thousands of visitors and garner national attention through dissemination efforts. Visitors to the exhibition and participants in related programs will come to a better understanding of the connections between biology and technology while learning of science and engineering's role in improving the quality of life in our society.