This virtual conference proposal would bring together NSF researchers and their media partners who worked collaboratively on previous NSF projects involved with communicating research to public audiences (the now archived CRPA program). The goal of the conference to is examine successful practices and lessons learned and aggregate the findings in a manner that can productively inform and support current and future efforts of this kind. The key objectives of the work will be to identify approaches that broaden reach, increase the effectiveness of researcher/outreach organizational partnerships, and make recommendations for amplifying the strategic impact of these projects. Prior to the conference the PI will conduct a multiphase process of document review, online interviews, and questionnaires. Two virtual workshops will be conducted with a subset of previous grantees and their media partners noted for effective collaboration and outcomes. The first workshop will have participants sharing findings on project strengths and areas needing improvement based on past experience. They will identify possible generic tools and a framework that could be shared across projects. The second workshop will focus on the identified successful strategies might be implemented more widely. The broader impacts of this multi-component conference will help future grantees better understand, expand, and work more strategically with their outreach partners.
The University of Pittsburgh's Center for Learning in Out-of-School Environments, the Carnegie Museum of Natural History, and the Robotics Institute at Carnegie Mellon University are building an open access cyberlearning infrastructure that employs super high-resolution gigapixel images as a tool to support public understanding, participation, and engagement with science. Networked, gigapixel image technology is an information and communication technology that creates zoomable images that viewers can explore, share, and discuss. The technology presents visual information of scientifically important content in such detail that it can be used to promote both scientific discovery and education. The purpose of the project is to make gigapixel technology accessible and usable for informal science educators and scientists by developing a robotic imaging device and online services for the creation, storage, and sharing of billion-pixel images of scientifically important content that can be analyzed visually. Project personnel are conducting design activities, user studies, and formative evaluation studies to support the development of a gigapan technology platform for demonstration and further prototyping. The project builds on and leverages existing technologies to provide informal science education organizations use of gigapixel technology for the purpose of facilitating three types of activities that promote participatory learning by the public--Public Understanding of Science activities; Public Participation in Scientific Research activities; and Public Engagement in Science activities. The long-terms goals of the work are to (1) create an accessible database of gigapixel images that informal science educators can use to facilitate public-scientist interactions and promote participatory science learning, (2) characterize and demonstrate the affordances of networked gigapixel technologies to support socially-mediated, science-focused cyberlearning experiences, (3) generate knowledge about how gigapixel technology can enable three types of learning interactions between scientists and the public around visual data, and (4) disseminate findings that describe the design, implementation, and evaluation of the gigapixel platform to support participatory science learning. The project's long-term strategic impacts include guiding the design of high-resolution images for promoting STEM learning in both informal and formal settings, developing an open educational resource and science communication platform, and informing informal science educators about the use and effectiveness of gigapixel images in promoting participatory science learning by the public.
The Cyberlearning and Future Learning Technologies Program funds efforts that support envisioning the future of learning technologies and advance what we know about how people learn in technology-rich environments. Development and Implementation (DIP) Projects build on proof-of-concept work that shows the possibilities of the proposed new type of learning technology, and PI teams build and refine a minimally-viable example of their proposed innovation that allows them to understand how such technology should be designed and used in the future and that allows them to answer questions about how people learn, how to foster or assess learning, and/or how to design for learning. This project is building and studying a new type of online learning community. The WeatherBlur community allows kids, teachers, scientists, fishermen/fisherwomen, and community members to learn and do science together related to the local impacts of weather and climate on their coastal communities. Members of the community propose investigations, collect and share data, and learn together. WeatherBlur is designed to be a new form of knowledge-building community, the Non-Hierarchical Online Learning Community. Unlike other citizen science efforts, there is an emphasis on having all members of the community able to propose and carry out investigations (and not just help collect data for investigations designed by expert scientists or teachers). Prior research has demonstrated important structural differences in WeatherBlur from other citizen science learning communities. The project will use social network analysis and discourse analysis to measure learning processes, and Personal Meaning Mapping and embedded assessments of science epistemology and graph interpretation skills to examine outcomes. The measures will be used to explore knowledge-building processes and the scaffolds required to support them, the negotiation of explanations and investigations across roles, and the epistemic features that drive this negotiation process. The work will be conducted using an iterative design-based research process in which the prior functioning WeatherBlur site will be enhanced with new automated prompt and notification systems that support the non-hierarchical nature of the community, as well as tools to embed assessment prompts that will gauge participants' data interpretation skills and epistemic beliefs. Exponential random graph modeling will be used to analyze the social network analysis data and test hypotheses about the relationship between social structures and outcomes.
This is the final report of the Open University’s RCUK-funded Public Engagement with Research Catalyst, ‘An open research university’, a project designed to create the conditions in which engaged research can flourish. The report describes an evidence-based strategy designed to embed engaged research within the University’s strategic planning for research and the operational practices of researchers. This programme of organisational change was informed by action research, working collaboratively with researchers at all levels across the institution to identify and implement strategies that
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TEAM MEMBERS:
Richard HollimanAnne AdamsTim BlackmanTrevor CollinsGareth DaviesSally DibbAnn GrandRichard HoltiFiona McKerlieNick MahonyNick Mahony
Advances in genomics are rapidly increasing our understanding of not only the human body, disease and health-related issues but how humans and other species interact and respond to changing environments. Genomics represents a scientific frontier that connects with individuals and families at the most personal level, with the potential to shape the future of human healthcare. However, advances in genomics and their implications for personalized medicine are far out-pacing public awareness and knowledge. The Connecticut Science Center and the University of Connecticut partnered under a National Science Foundation funded collaboration between Dr. Rachel O'Neill, UCONN, and Dr. Hank Gruner, Connecticut Science Center, and the National Center for Science & Civic Engagement to engage the public in developing a conceptual understanding of genomics.
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TEAM MEMBERS:
Connecticut Science CenterRachel O'NeillHank Gruner
Public Television station WQED/Pittsburgh, in partnership with five medical research and clinical centers, proposes to develop, test and distribute a national biomedical video education program based on "The Universe Within," a planned PBS series. The project is intended to bring scientists and clinicians into closer contact with pre-college students to study human body systems and increase career interest in the life sciences. Designed to improve science education and literacy, the project will also enhance overall appreciation of achievements in biomedicine. Using advanced television, photographic and animation techniques, the project will create a collection of educational tools for use by science and health teachers as well as by scientific investigators and clinicians. These modules will demonstrate how most of the body's primary systems function and how they can be kept healthy. The approach will combine visual and print curriculum materials with the personal presence of medical scientists, thus providing an opportunity for students to develop interest, critical thinking and problem-solving skills. This flexible educational package can be updated as important new changes occur in medical science, thus extending the life of costly materials. In addition, through multiple narration tracks, the video elements can be customized for various levels of age and grade instruction.
The overall goal of the current proposal is to adapt the interdisciplinary research-based curriculum created at the School for Science and Math at Vanderbilt (SSMV) for implementation of a four-year program in three Metropolitan Nashville Public School (MNPS) high schools. The specific aims of the proposal are to adapt the on-campus (at Vanderbilt) model for implementation in three public high schools with different academic profiles (SSM Academies); to define the variables and features required to sustain the program and to replicate the model in any high school setting; and to define a strategy for disseminating the model to additional schools. Students entering 9th grade in a school in which an SSM Academy has been implemented will be encouraged to apply. Those who are accepted into the program will spend three hours every other day in two courses based on the adapted curriculum. As with the SSMV, rising seniors will have opportunities to enter Vanderbilt laboratories for summer research internships. Teachers from the high school will work with Center for Science Outreach scientists to adapt the SSMV curriculum for implementation. Ongoing, year-long teacher professional development will be conducted to ensure that the curriculum is dynamic and the teachers are well-prepared to engage and guide the students in the curriculum. The anticipated outcomes include enhanced student achievement as measured by GPA, and scores on ACT science reasoning and end of course tests; increased SSM student interest in careers in science; increased district-wide enrollment in SSM programs; increased graduation rates and postsecondary education enrollment by SSM students; development of unique curricular science units that can be adapted for a novel four-year interdisciplinary research- based curriculum; development of a sustainable model built on effective features of each SSM that can be exported to other high schools within and outside Nashville; enhanced community and family involvement in the SSM programs and school community in general; a strengthened partnership between Vanderbilt and MNPS that will serve as a national model of a successful university-K-12 collaboration to enhance science teaching and learning.
The Science Museum of Minnesota (SMM) requests a grant from the National Center for Research Resources through the SEPA program to develop and evaluate a model biomedical science education partnership program in collaboration with the University of Minnesota's Cancer Center, Medical School, School of Public Health, and College of Veterinary Medicine. The museum will work with 19 researchers at the University to develop a multifaceted exhibition and presentation program focusing on the importance of human tissues in biological development, function, and disease. The 1500-square-foot exhibition, to be located in SMM's new Human Body Gallery, will consist of an introduction to tissues and four topical exhibit clusters. Each topic was chosen because it tells a fascinating story of how the human body works and because it represents an important current NIH research focus in health and medicine. The exhibits will emphasize the importance of understanding how tissue function and viability leads to advances in detection, treatment, and curing different diseases. The exhibits closely support the National Science Education Standards Content Standards for Life Science for grades 5-9 (representing the majority of school field trip visitors to the museum.) A complimentary presentation/outreach program will involve NIH-supported researchers in three programs designed to increase public understanding of basic biomedical science, the causes and cures for disease, and the goals and achievements of biomedical research. A Visiting Scientists Program will feature scientists in the museum presenting programs and demonstrations related to their research interests. A Scientist Mentor Program will involve scientists closely with a diverse team of high-school aged youth to develop ongoing demonstrations and community outreach programs. A Dramatic Presentation will bring home to museum visitors the wider ethical and philosophical dimensions of tissue research.
Through "Addressing the Science of Really Gross Things: Engaging Young Learners in Biomedical Science Through a Fulldome Planetarium Show and Supporting Curricula," Morehead Planetarium and Science Center at the University of North Carolina at Chapel Hill, in close collaboration with NIH-funded researchers at the UNC and a leading children's book author, will develop an informal science education media project and a suite of hands-on, inquiry-based curricula based on the media project for use in science centers, museums and schools. This project will build the pipeline of future researchers and create awareness of NIH-funded research by generating interest and excitement among children age 9-13 in the health sciences and related careers and building their science content knowledge. To achieve the objective, the investigators will develop a fulldome planetarium show; create correlating curricula for summer camps, afterschool programs, scout programs, science center field trips, science clubs and schools; and produce a DVD highlighting careers in the health sciences. In addition, the project will use several methods to target populations traditionally underrepresented in the biomedical fields, including featuring professionals from underrepresented populations in the multimedia and curricula products, making outreach visits to counties with large populations traditionally underrepresented in health science research careers, and producing a Spanish-language version of the products. The use of a known brand, "Grossology," is an innovative way to connect to children in the target age range and to encourage the informal science education community to embrace health-science content in their fulldome theaters. In addition, the project's hub-and-spoke approach further encourages adoption of this programming by providing informal science venues with both an engaging experience (hub) and the supporting curricula (the spokes) that is necessary to extend the show's potential for having significant educational impact. A strong project team maximizes the project's likelihood for success. The team includes fulldome producers and educators from Morehead and NIH-funded researchers with expertise in appropriate science content areas. In addition, the investigators have created a network of consultants, advisory board members and evaluators that will create feedback loops designed to ensure high-quality, scientifically-accurate, educationally-effective products. The investigators will use a combination of free and revenue-based dissemination strategies to ensure that the products of this award are broadly distributed. These strategies hold significant promise for creating broad use of this project's products in the nation's science centers, museums and classrooms.
This Phase I SEPA proposal supports a consortium of science and education partners that will develop System Dynamics (SD) computer models to illustrate basic health science concepts. The consortium includes Oregon Health Sciences University (OHSU), Portland Public Schools (PPS), Saturday Academy, and the Portland VA Medical Center. SD is a computer modeling technique in which diagrams illustrate system structure and simulations illustrate system behavior. Desktop computers and commercial software packages allow SD to be applied with considerable success in K-12 education. NSF grants to Portland Public Schools have trained over 225 high school teachers in Portland and surrounding areas. Two magnet programs have been established with an emphasis on systems and at least five other schools offer significant systems curriculum. Major components of this project include (1) Annual summer research internships at OHSU for high school teachers and high school students, (2) Development of SD models relevant to each research project, (3) Ongoing interactions between high school science programs and OHSU research laboratories, (4) Development of curriculum materials to augment the use of the SD model in the high school classroom or laboratory setting, and (5) Development of video materials to support the classroom teacher. Content will focus on four fundamental models: linear input/exponential output, bi-molecular binding (association/dissociation), population dynamics, and homeostasis. Each of these models is very rich and may be extended to a broad variety of research problems. In addition these models may be combined, for example to illustrate the effect of drugs (binding model) on blood pressure (homeostasis model). System Dynamics is an exemplary tool for the development of materials consistent with National Science Education Standards. SD was specifically developed to emphasize interactions among system structure, organization, and behavior. Students use these material as part of inquiry-based science programs in which the teacher serves as a guide and facilitator rather than the primary source of all content information; technical writing by students is also encouraged. Finally, these SD materials will provide a coherent body of work to guide the ongoing professional development of the classroom science teacher.
Serial Passage: AIDS, Race, and Culture is a multi-part documentary series. The Long-term goals are: 1) to produce a documentary series exploring the specific and devastating impact of H.I.V./AIDS upon Africans and African-Americans; and 2) to create a heightened understanding of the need for H.I.V. prevention among the high-risk group of young, inner-city African-Americans who've so far proved unresponsive to available public health information. Specific Aims: 1) To deconstruct the racial stigma of AIDS, and scientifically confront the conspiracy theories which are firmly linked to the disease in black America, and in Africa; and 2) to work with an inner-city high school science class, actively involving them in the making of the series. Research Design and Methods: 1) To document on film the process of scientific inquiry which led two prominent researchers to their theory on the origin of AIDS; 2) To document on film the social impact of H.I.V/AIDS upon specific African countries, including Uganda and South Africa, and upon African-American communities in the United States; 3) To periodically screen footage of the documentary for the high school class and conduct videotaped discussions between the students and the scientists throughout one academic year; and 4) To give the students a videotaped questionnaire at the beginning and end of the year designed to measure how much they learn about AIDS and its impact upon their particular community.
In January 2006, the Dolan DNA Learning Center launched its SEPA Phase I project: Inside Cancer, a media-rich internet site that examines the molecular genetic basis of cancer. We now propose a Phase II Project, which will employ a six-part strategy to broadly disseminate the site and evaluate its use as a resource in high school biology and health education. a) A partnership will disseminate the site to 800 secondary science teachers at one-day workshop held at 20 sites nationwide. This cost-effective program will focus on key concepts and relevant teaching standards, and also provide a dedicated base for conducting second-round training and evaluation activities. b) An online Teacher Center will allow teachers to develop custom multimedia lessons based on Inside Cancer materials. Key features will be a Concept Matrix, Lesson Exchange, and Atomizer, which will match content with teaching standards, facilitate a community approach to lesson plan development, and provide a searchable interface of over 3,000 multimedia content "atoms." c) Fellowships will allow three lead faculty to work directly with DNALC staff to develop the Teacher Center and model lesson plans (DNALC Fellows). Eighty workshop alumni will serve as Regional Fellows and receive stipends to conduct second-round training activities reaching 640 additional teachers. d) An annual review will assess fidelity to project objectives and analyze site logs to detect patterns of use. An online survey of 1,500 Inside Cancer users annually will assess differences in site use among teachers, students, science and medical professionals, and the general public. e) A longitudinal evaluation of 1,440 participants in workshops and second-round activities will gauge how teachers use Inside Cancer and the Teacher Center, and how their teaching behavior changes over time. f) A controlled study will compare attitudinal and learning effects among 280 high school students - half of whom use Inside Cancer in their classes an half who don't. Biology and health classes will be selected from a single school district that reflects the ethnic and racial distribution of the U.S. population.