Hopa Mountain, working in partnership with Montana State University (MSU), will develop innovative and coordinated opportunities for Montana youth to strengthen their STEM (Science, Technology, Engineering and Mathematics) skills and knowledge while preparing them for higher education and careers in health sciences. The overall project goal of HealthMakers is to support rural and tribal youth’s interest and exposure to careers in the sciences while giving them the skills and resources to play leadership roles in increasing healthy family practices in their homes and communities. HealthMakers will achieve meaningful impacts annually through four strategies: (1) Health-focused college preparation programs for 50 teens; (2) Summer academic enrichment programs for 20 teens; (3) Community-based science literacy events for 2,000 children and their families, and (4) Professional development for educators, community members, and parents. Hopa Mountain and MSU will engage youth, educators, community leaders, and parents in training opportunities through HealthMakers. Participants will take part in community-based workshops, college tours, and summer institutes led by MSU faculty, healthcare professionals, Hopa Mountain staff, and their peers. Through these strategic aims, HealthMakers will help create a stronger workforce and inspire students to pursue careers in the sciences.
PUBLIC HEALTH RELEVANCE:
HealthMakers will support the development of health-related outreach and college preparation programs and training resources to create a better-informed workforce for Montana and inspire students to pursue careers in the sciences. These strategic aims and deliverables benefiting rural and tribal families and children, will help create a stronger workforce and inspire students to pursue careers in the sciences. Working together, Hopa Mountain and Montana State University will support rural and tribal youth’s interest and exposure to careers in the health sciences while giving them the skills and resources to play leadership roles in increasing healthy family practices in their communities.
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TEAM MEMBERS:
Bonnie Sacchatello-Sawyer
resourceresearchProfessional Development, Conferences, and Networks
BioEYES is a K-12 science outreach program that develops self-sustaining teachers as a replication strategy to address high demand for the program while promoting long-term school partnerships. This paper explores the practices of “model teachers” from multiple grades, who are empowered over a three-year period to deliver BioEYES’ hands-on science content autonomously, as compared to the program’s standard co-teaching model (BioEYES educator + classroom teacher). The authors found that BioEYES’ professional development (PD) workshop, classroom co-teaching experience, and refresher trainings
The Exploratorium Teacher Institute (TI) is a teacher professional development center that offers comprehensive, multiyear professional learning institutes; classroom coaching and mentoring; and teaching tools to middle and high school science teachers. The TI staff is composed of a team of PhD scientists and veteran secondary science educators who work in concert to provide teachers with resources and experiences that develop the content knowledge and pedagogical skills necessary for teaching authentic science content through student-centered activities (McDermott and DeWater 2000). All of
People of color who live in low income, urban communities experience lower levels of educational attainment than whites and continue to be underrepresented in science at all educational and professional levels. It is widely accepted that this underrepresentation in science is related, not only to processes of historical exclusion and racism, but to how science is commonly taught and that investigating authentic, relevant science questions can improve engagement and learning of underrepresented students. Approaching science in these ways, however, requires new teaching practices, including ways of relating cross-culturally. In addition to inequity in science and broader educational outcomes, people of color from low income, urban communities experience high rates of certain health problems that can be directly or indirectly linked to mosquitoes. Recognizing that undertaking public health research and preventative outreach efforts in these communities is challenging, there is a critical need for an innovative approach that leverages local youth resources for epidemiological inquiry and education. Such an approach would motivate the pursuit of science among historically-excluded youth while, additionally, involving pre-service, in-service, and informal educators in joint participatory inquiry structured around opportunities to learn and practice authentic, ambitious science teaching and learning.
Our long-term goal is to interrupt the reproduction of educational and health disparities in a low-income, urban context and to support historically-excluded youth in their trajectories toward science. This will be accomplished through the overall objective of this project to promote authentic science, ambitious teaching, and an orientation to science pursuits among elementary students participating in a university-school-community partnership promise program, through inquiry focused on mosquitoes and human health. The following specific aims will be pursued in support of the objective:
1. Historically-excluded youth will develop authentic science knowledge, skills, and dispositions, as well as curiosity, interest, and positive identification with science, and motivation for continued science study by participating in a scientific community and engaging in the activities and discourses of the discipline. Teams of students and educators will engage in community-based participatory research aimed at assessing and responding to health and well-being issues that are linked to mosquitoes in urban, low-income communities. In addition, the study of mosquitoes will engage student curiosity and interest, enhance their positive identification with science, and motivate their continued study.
2. Informal and formal science educators will demonstrate competence in authentic and ambitious science teaching and model an affirming orientation toward cultural diversity in science. Pre-service, in-service, and informal educators will participate in courses and summer institutes where they will be exposed to ambitious teaching practices and gain proficiency, through reflective processes such as video study, in adapting traditional science curricula to authentic science goals that meet the needs of historically excluded youth.
3. Residents in the community will display more accurate understandings and transformed practices with respect to mosquitoes in the urban ecosystem in service of enhanced health and well-being. Residents will learn from an array of youth-produced, culturally responsive educational materials that will be part of an ongoing outreach and prevention campaign to raise community awareness of the interplay between humans and mosquitoes.
These outcomes are expected to have an important positive impact because they have potential for improving both immediate and long-term educational and health outcomes of youth and other residents in a low-income, urban community.
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TEAM MEMBERS:
Katherine Richardson BrunaLyric Colleen Bartholomay
Recruiting more research scientists from rural Appalachia is essential for reducing the critical public health disparities found in this region. As a designated medically underserved area, the people of Appalachia endure limited access to healthcare and accompanying public health education, and exhibit higher disease incidences and shorter lifespans than the conventional U.S. population (Pollard & Jacobsen, 2013). These health concerns, coupled with the fact that rural Appalachian adults are less likely to trust people from outside their communities, highlights the need for rural Appalachian youth to enter the biomedical, behavioral, and clinical research workforce. However, doing so requires not only the specific desire to pursue a science, technology, engineering, math, or medical science (STEMM) related degree, it also requires the more general desire to pursue post-secondary education at all. This is clearly not occurring in Tennessee’s rural Appalachian regions where nearly 75% of adults realize educational achievements only up to the high school level. Although a great deal of research and intervention has been done to increase students’ interest in STEMM disciplines, very little research has considered the unique barriers to higher education experienced by rural Appalachian youth. A critical gap in past interventions research is the failure to address these key pieces of the puzzle: combatting real and perceived barriers to higher education and STEMM pursuits in order to increase self-efficacy for, belief in the value of, and interest in pursuing an undergraduate degree. Such barriers are especially salient for rural Appalachian youth.
Our long-range goal is to increase the diversity of biomedical, clinical and behavioral research scientists by developing interventions that both reduce barriers to higher education and increase interest in pipeline STEMM majors among rural Appalachian high school students. Our objective in this application is to determine the extent to which a multifaceted intervention strategy combining interventions to address the barriers to and supports for higher education with interventions to increase interest in STEMM fields leads to increased intentions to pursue an undergraduate STEMM degree. Our hypothesis is that students who experience such interventions will show increases in important intrapersonal social-cognitive factors and in their intentions to pursue a postsecondary degree than students not exposed to such interventions. Based on the low numbers of students from this region who pursue post-secondary education and the research demonstrating the unique barriers faced by this and similar populations (Gibbons & Borders, 2010), we believe it is necessary to reduce perceived barriers to college-going in addition to helping students explore STEMM career options. In other words, it is not enough to simply offer immersive and hands-on research and exploratory career experiences to rural Appalachian youth; they need targeted interventions to help them understand college life, navigate financial planning for college, strategize ways to succeed in college, and interact with college-educated role models. Only this combination of general college-going and specific STEMM-field information can overcome the barriers faced by this population. Therefore, our specific aims are:
Specific Aim 1: Understand the role of barriers to and support for higher education in Appalachian high school students’ interest in pursuing STEMM-related undergraduate degrees. We will compare outcomes for students who participate in our interventions, designed to proactively reduce general college-going barriers while increasing support systems, to outcomes for students from closely matched schools who do not participate in these interventions to determine the extent to which such low-cost interventions, which can reach large numbers of students, are effective in increasing rural Appalachian youth’s intent to pursue STEMM-related undergraduate degrees.
Specific Aim 2: Develop sustainable interventions that decrease barriers to and increase support for higher education and that increase STEMM-related self-efficacy and interest. Throughout our project, we will integrate training for teachers and school counselors, nurture lasting community partnerships, and develop a website with comprehensive training modules to allow the schools to continue implementing the major features of the interventions long after funding ends.
This research is innovative because it is among the first to recognize the unique needs of this region by directly addressing barriers to and supports for higher education and integrating such barriers-focused interventions with more typical STEMM-focused interventions. Our model provides opportunities to assess college-going and STEMM-specific self-efficacy, outcome expectations, and barriers/supports, giving us a true understanding of how to best serve this group. Ultimately, this project will allow future researchers to understand the complex balance of services needed to increase the number of rural Appalachians entering the biomedical, behavioral, and clinical research science workforce.
The goal of the Hawaii Science Career Inspiration grant (HiSCI) is to enhance science education resources and training available to teachers and students in disadvantaged communities of Hawaii in order to ensure a maximally large and diverse workforce to meet the nation’s biomedical, behavioural and clinical research needs. The HiSCI Program will build on the knowledge gained from two past SEPA grants and the University of Hawaii Center for Cardiovascular Research and leverage resources from all corners of the state to accomplish four specific aims:
1) Increase student interest and exposure to health science careers by providing multiple science exposure opportunities and mentoring along the primary, intermediate, and secondary school experiences for at least 300 students a year and a printed and web-based STEM career resource guide and career posters to alert students, counsellors and teachers to all available opportunities;
2) Provide professional development for 20 middle and high school teachers a year, to include scientific content and foster an understanding of the scientific research process, in addition to medical students mentoring intermediate and high school students;
3) Listen, respond to, and connect the science teacher community in Hawaii by holding innovative listening groups for teachers across the state; and
4) Provide tools and supplies for at least twenty K-12 classrooms a year through a mini-grant process and alert teachers across the state to free resources both locally and nationally. The HiSCI Program is highly relevant to Hawaii’s public health and science infrastructure as it will provide an innovative way to gain knowledge of science training needs and will provide many of the resources to teachers and students across the state by leveraging, communicating and sharing existing resources.
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
The Peabody Museum of Natural History's program on Biodiversity and Vector-Borne Disease was successful in meeting all of its goals. The following is a summary of the program in terms of these goals. Goal 1: To build teacher capacity for bringing research in biodiversity and disease ecology to grades 5-11 in an engaging, inquiry-based style. A total of 64 teachers from Connecticut and 4 teacher-trainers from California, Texas, and Wisconsin participated in training institutes to learn about vector-borne diseases. All participating teachers successfully implemented most or all of the curriculum
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Minda BorunPeabody Museum of Natural History
The goal of a two-year SEPA grant, Phase II of a collaboration between Columbia University (CU) and the New York Hall of Science (NYHoS), was to enhance science teaching and learning through the use of portable laboratories and hands-on modules to study biotechnology and microscopy in middle and secondary school classes. Four multi-day workshops were held at the NYHoS to train teachers to use the portable laboratory kits. The primary goals of this evaluation are to assess: 1) the workshops' value for teaching the hands-on kit curriculum, 2) teachers' perception of the portable laboratories'
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Ellen GiustiNew York Hall of Science
The primary purpose of the proposed grant is to support the dissemination and institutionalization of a model of educational partnerships among academic medical centers, undergraduate colleges, and local school systems. This model was created under the umbrella of AAMC's Project 3000 by 2000 . With support from SEPA, during 1994-1997 we will consolidate and extend the accomplishments we achieved under our original SEPA, 1991-1994 (SEPA-I). In 1991, the AAMC began Project 3000 by 2000 . The activities included in this proposal support Project 3000 by 2000 , but are not designed to only recruit students for medical school. Minority underrepresentation in medical schools largely is due to the same fundamental problem that causes minority underrepresentation in health-related Ph.D. programs: an insufficient number of minority students receive adequate academic preparation-especially in the sciences-prior to college. The projects proposed here are designed to address this basic problem and hence promote greater racial and ethnic diversity in all of the health sciences. Eight programmatic activities are proposed, five of which were initiated during SEPA I: (1) The annual publication of the Secondary School Science Minority Achievement Registry (S 3 MAR) , a directory of educational programs for minority students interested in the health sciences and a registry of the students participating in them; (2) NNHeSPA News , the quarterly newsletter of the National Network for Health Science Partnerships ( NNHeSPA) ; (4) An update of the Project 3000 by 2000 Technical Assistance Manual (Volume II); (5) Presentations to a wide variety of groups and strategically targeted customized data analysis. New projects include: (6) NNHeSPA On Line!, a computer bulletin board accessible through the Internet to facilitate ongoing communication among precollege, college and graduate health science educators in NNHeSPA ; (7) S 3 MAR Grapevine , a quarterly newsletter for high school stuents listed in the S 3 MAR ; (8) Intensive regional campaigns to promote health science partnerships in California, Texas, and the South-three areas of the country with large minority populations and severe problems of underrepresentation.
Goals: 1) Increase the number of Alaskans from educationally and/or economically disadvantaged backgrounds, particularly Alaska Natives, who pursue careers in health sciences and health professions and 2) Inform the Alaskan public about health science research and the clinical trial process so that they are better equipped to make healthier lifestyle choices and better understand the aims and benefits of clinical research. Objectives: 1) Pre-med Summer Enrichment program (U-DOC) at UAA (pipeline into college), 2) Statewide Alaska Student Scientist Corps for U-DOC, 3) students (pipeline into college), 4) Facility-based Student Science Guide program at Imaginarium Science Discovery Center, 5) Job Shadowing/Mentorship Program for U-DOC students and biomedical researchers, 6) Research-based and student-led exhibit, demonstration, and multi-media presentations, 7) Professional Development for educators, 8) North Star Website.
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.