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1. Bringing Research into the Classroom: Bacteriophage Discovery Connecting University Scientists, Students, and Faculty to Rural K-12 Teachers, Students, and Administrators

   https://doi.org/10.15695/jstem/v7i2.08  

   Brandl, Rayelynn L; Pavlovich, Christina L; Pedulla, Marisa L (February 2024, The Journal of STEM Outreach)

   Bringing Research into the Classroom (BRIC) engaged rural K-12 science teachers in sustained, mentored science research. BRIC’s goal was to equip teachers with the knowledge, skills, and dispositions to provide high-quality biomedical research opportunities for K-12 students and teachers. Programmatic elements included authentic, place-based, microbiology outreach in K-12 classrooms, summer teacher research academies focused on content knowledge and research, and a capstone symposium. Over 9,000 Montana students collected and tested environmental samples to isolate new-toscience bacteriophages (viruses that infect bacteria). University scientists, faculty, and students mentored K-12 teachers and students during classroom outreach visits and teacher research academies. BRIC aimed to increase teacher and student bacteriophage content knowledge and research skills through meaningful, mentored research projects. BRIC researchers hypothesized greater program impacts from intensive teacher professional development combined with classroom outreach, compared to classroom outreach visits alone. Program evaluation compared two cohorts of teachers, which each received all programmatic elements through a four-year, staggered rollout. Teachers and students were assessed for gains in knowledge, skills, and science attitudes. A subset of our evaluation instruments and outcomes, program dissemination, lessons learned, and recommendations for replicating the BRIC model are discussed. 

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2. Biological Field Stations Promote Science Literacy through Outreach

   https://doi.org/10.1093/biosci/biab057  

   Struminger, Rhonda; Short, Rachel A; Zarestky, Jill; Vilen, Lauren; Lawing, A Michelle (May 2021, BioScience)

   null (Ed.)

   Abstract Biological field stations (BFSs) are well positioned through their informal STEM (science, technology, engineering, and mathematics) education programs to improve levels of science literacy and support environmental sustainability. A survey of 223 US BFSs revealed that their outreach programs strive to promote conservation and environmental stewardship in addition to disseminating place-based knowledge and/or skills. In this article, we unpack the educational approaches that BFSs use to engage learners, the aspects of science literacy most often addressed, and the perceived learning outcomes. Most notably, the BFSs reported that their participants develop an interest in and excitement for science, increase or change their knowledge of program topics, identify more with the scientific enterprise, and engage in scientific practices. The results indicate opportunities for BFSs to conduct more rigorous assessments of participant learning and program impact. By focusing on learner engagement, science learning, and participant outcomes, BFSs and other place-based informal education venues can expand their efforts and better support conservation and science learning. 

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3. Partnering to Develop a Coordinated Engineering Education Program Across Schools, Museum Field Trips, and Afterschool Programs

   Harlow, D. (January 2020, Connected science learning)

   Engineering Explorations are curriculum modules that engage children across contexts in learning about science and engineering. We used them to leverage multiple education sectors (K–12 schools, museums, higher education, and afterschool programs) across a community to provide engineering learning experiences for youth, while increasing local teachers’ capacity to deliver high-quality engineering learning opportunities that align with school standards. Focusing on multiple partners that serve youth in the same community provides opportunities for long-term collaborations and programs developed in response to local needs. In a significant shift from earlier sets of standards, the Next Generation Science Standards include engineering design, with the goal of providing students with a foundation “to better engage in and aspire to solve the major societal and environmental challenges they will face in decades ahead” (NGSS Lead States 2013, Appendix I). Including engineering in K–12 standards is a positive step forward in introducing students to engineering; however, K–12 teachers are not prepared to facilitate high-quality engineering activities. Research has consistently shown that elementary teachers are not confident in teaching science, especially physical science, and generally have little knowledge of engineering (Trygstad 2013). K–12 teachers, therefore, will need support. Our goal was to create a program that took advantage of the varied resources across a STEM (science, technology, engineering, and math) education ecosystem to support engineering instruction for youth across multiple contexts, while building the capacity of educators and meeting the needs of each organization. Specifically, we developed mutually reinforcing classroom and field trip activities to improve student learning and a curriculum to improve teacher learning. This challenging task required expertise in school-based standards, engineering education, informal education, teacher professional development, and classroom and museum contexts. 

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4. Predicting Engineering Integration in K-12 from the Perspective of Pre-service Teachers

   Pazos, P.; Cima, F.; Kidd, J.; Gutierrez, K.; Faulkner, D.; Lee, M.; Kaipa, K. & (January 2023, IJEE International Journal of Engineering Education)

   The integration of engineering content at the pre-college level is gaining global traction as a strategy to improve learning outcomes and to promote inclusion and diversity in STEM (Science, Technology, Engineering, and Mathematics). Preservice teacher programs have become natural insertion points for integration efforts by providing future K-12 teachers with the resources and preparation to teach engineering as part of their academic preparation. There is a need to understand the socio-cognitive mechanisms by which teacher preparation programs can help teachers to integrate engineering in their future classrooms. This work examines how an innovative cross disciplinary program impacted important social-cognitive drivers of engineering integration. We used mediation analysis to understand a successful pathway to engineering integration as a result of exposure to a cross-disciplinary collaboration with engineering students. This study revealed how participation in the program as part of their academic preparation increased PTSs’ confidence to teach engineering and their beliefs about the importance of engineering content, which in turn, increased their intention to integrate engineering in the classroom. 

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5. K-12 Education in the Age of AI: A Call to Action for K-12 AI Literacy

   https://doi.org/10.1007/s40593-023-00358-x  

   Wang, N; Lester, J (June 2023, International journal of artificial intelligence in education)

   The emergence of increasingly powerful AI technologies calls for the design and development of K-12 AI literacy curricula that can support students who will be entering a profoundly changed labor market. However, developing, implementing, and scaling AI literacy curricula poses significant challenges. It will be essential to develop a robust, evidence-based AI education research foundation that can inform AI literacy curriculum development. Unlike K-12 science and mathematics education, there is not currently a research foundation for K-12 AI education. In this article we provide a component-based definition of AI literacy, present the need for implementing AI literacy education across all grade bands, and argue for the creation of research programs across four areas of AI education: (1) K-12 AI Learning & Technology; (2) K-12 AI Education Integration into STEM, Language Arts, and Social Science Education; (3) K-12 AI Professional Development for Teachers and Administrators; and (4) K-12 AI Assessment. 

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