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1. Transforming STEM Instruction Through SocioScientific Issues Focused Professional Development

   Johnson, Joseph; Mathers, Becky; Marco-Bujosa, Lisa; Ialacci, Gabrielle (June 2024, International journal on new trends in education and their implications)

   This study reports the findings of a two-year intensive professional development (PD) program situated in the northeastern United States for secondary mathematics and science teachers to support them in transforming their STEM instruction to incorporate SocioScientific Issues (SSI). This PD focused on developing units of study that integrated student-centered, authentic learning experiences grounded in social justice issues. Findings indicate that after participation in the USTRIVE project, teachers displayed growth in their ability to incorporate components of the instructional framework for SSI introduced in the PD into their teaching. This is consistent with previous research that SSI-focused PD can increase teachers’ knowledge of, and teaching practices toward SSI, resulting in more meaningful STEM learning experiences for students. As such, the USTRIVE PD model and framework may provide a useful guide for other SSI and social justice PD programs. Connections of these findings to student engagement, teachers learning, and challenges encountered in SSI implementation are explored. 

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2. Building Resilience in Rural STEM Teachers Through a Noyce Professional Learning Community

   https://doi.org/10.3390/educsci15010085  

   Vestal, Sharon S; Burke, Robert S; Browning, Larry M; Hasselquist, Laura; Hales, Patrick D; Miller, Matthew L; Nepal, Madhav P; White, P Troy (January 2025, Education Sciences)

   Peña-Martínez, Juan (Ed.)

   Addressing the critical STEM teachers’ shortage in the rural United States requires not only recruiting new teachers but also improving retention and teacher resiliency. This study explores contextual protective factors through the Early Career Teacher Resilience (ECTR) framework. The major objective of this study was to evaluate the impacts of the NSF Noyce Professional Learning Community (PLC) on rural STEM teacher resilience. Key components of the Noyce PLC included scholarship support, pre-service mentoring, attendance at local and regional educational events, active engagement in the program’s annual summer conference, and participation in a closed Facebook group. We developed an ECTR framework-based online instrument with 28 questions and sent it to 311 university alumni, including 44 Noyce alumni. The results suggest that the Noyce PLC has excelled in fostering collaborative learning environments, providing resources that enhance teaching and learning, accommodating new and different ways of thinking, and supporting teachers’ professional growth beyond graduation. The findings underscore the importance of integrating theoretical and practical knowledge, supporting ongoing professional learning, and building strong professional relationships. Several aspects of the Noyce PLC could be replicated in other STEM teacher preparation programs to enhance teacher resilience, effectiveness, and career development. 

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3. Transcending disciplines: Engaging college students in interdisciplinary research, integrated STEM, and partnerships

   https://doi.org/10.3926/jotse.1139  

   Kilty, Trina; Burrows, Andrea; Welsh, Kate; Kilty, Kevin; McBride, Shawna; Bergmaier, Philip (February 2021, Journal of Technology and Science Education)

   An authentic, interdisciplinary, research and problem-based integrated science, technology, engineering, and mathematics (STEM) project may be ideal for encouraging scientific inquiry and developing teamwork among undergraduate students, but it also presents challenges. The authors describe how two interdisciplinary teams (n=6) of undergraduate college students built integrated STEM projects in a research based internship setting, and then collaboratively brought the project to fruition to include designing lessons and activities shared with K-12 students in a classroom setting. Each three person undergraduate team consisted of two STEM majors and one Education major. The Education majors are a special focus for this study. Interviews, field observations, and lesson plan artifacts collected from the undergraduate college students were analyzed according to authenticity factors, the authentic scientific inquiry instrument, and an integrated STEM instrument. The authors highlight areas of strength and weakness for both teams and explore how preservice teachers contributed to integrated STEM products and lessons. Teacher educators might apply recommendations for teacher preparation and professional development when facilitating authentic scientific inquiry and integrated STEM topics with both STEM and non-STEM educators. Undergraduate college students were challenged to fully integrate the STEM disciplines, transitions between them, and the spaces between them where multiple disciplines existed. By describing the challenges of integrating the spaces between STEM, the authors offer a description of the undergraduate college students’ experiences in an effort to expand the common message beyond a flat approach of try this activity because it works, to a more robust message of try this type of engagement and purposefully organize for maximum results. 

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4. Bridging Culture and Code: Culturally Responsive Computing Through Teacher-Led Curriculum Design

   https://doi.org/10.1145/3702653  

   Yan, W; Amresh, A; Parekh, P; Prescott, P (August 2025, ACM)

   Porter, Leo; Brown, Neil; Morrison, Briana; Montero, Calkin (Ed.)

   Indigenous communities remain significantly underrepresented in computer science (CS) and STEM fields, facing persistent barriers such as limited access to resources, infrastructure, and culturally relevant instruction. This study investigated how educators serving Indigenous populations designed and implemented culturally responsive computing (CRC)[2] curricula within a long-term professional development program grounded in a design-based research framework. The study examined how sustained, collaborative support enabled educators to effectively integrate Indigenous cultural knowledge, values, and practices into computer science education. Seven secondary teachers who work in schools in Arizona and New Mexico with over 90% Native American enrollment participated in a two-year professional development program called Let’s Talk Code Teaching Fellow. The program consisted of twelve online modules,weekly virtual meetings, in-personworkshops, and conference participation[3]. Following the DBR framework [1], teachers engaged in iterative cycles of lesson design, implementation, and revision, creating and teaching three culturally relevant computer science lessons. They received feedback from fellow teachers and research teams, allowing them to improve the connection between computing and cultural relevance in their lessons. The study employed a mixed-methods approach to data collection and analysis. Qualitative data included 14 finalized lesson plans, teacher reflections, teacher interviews, and classroom observation notes, which were thematically analyzed to identify common instructional practices and challenges, as well as strategies that connect culture and computing. Our findings showed that teachers sustained local culture by integrating Indigenous languages and art and innovative computing tools such as Scratch, micro: bit, and Sphero robots into their computing lessons. Teachers reported an increase in their confidence in computer science instruction following the long-term PD and benefited from a strong professional learning community. 

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5. Partnering Middle School Teachers, Industry, and Academic to Bring Engineering to the Science Classroom

   Carrico, C.; Grohs, J.R.; Matusovich, H.M.; Kirk, G.R.; Schilling, M.R. (July 2021, 2021 ASEE Virtual Annual Conference Content Access)

   Despite limited success in broadening participation in engineering with rural and Appalachian youth, there remain challenges such as misunderstandings around engineering careers, misalignments with youth’s sociocultural background, and other environmental barriers. In addition, middle school science teachers may be unfamiliar with engineering or how to integrate engineering concepts into science lessons. Furthermore, teachers interested in incorporating engineering into their curriculum may not have the time or resources to do so. The result may be single interventions such as a professional development workshop for teachers or a career day for students. However, those are unlikely to cause major change or sustained interest development. To address these challenges, we have undertaken our NSF ITEST project titled, Virginia Tech Partnering with Educators and Engineers in Rural Schools (VT PEERS). Through this project, we sought to improve youth awareness of and preparation for engineering related careers and educational pathways. Utilizing regular engagement in engineering-aligned classroom activities and culturally relevant programming, we sought to spark an interest with some students. In addition, our project involves a partnership with teachers, school districts, and local industry to provide a holistic and, hopefully, sustainable influence. By engaging over time we aspired to promote sustainability beyond this NSF project via increased teacher confidence with engineering related activities, continued integration within their science curriculum, and continued relationships with local industry. From the 2017-2020 school years the project has been in seven schools across three rural counties. Each year a grade level was added; that is, the teachers and students from the first year remained for all three years. Year 1 included eight 6th grade science teachers, year 2 added eight 7th grade science teachers, and year 3 added three 8th grade science teachers and a career and technology teacher. The number of students increased from over 500 students in year 1 to over 2500 in year 3. Our three industry partners have remained active throughout the project. During the third and final year in the classrooms, we focused on the sustainable aspects of the project. In particular, on how the intervention support has evolved each year based on data, support requests from the school divisions, and in scaffolding “ownership” of the engineering activities. Qualitative data were used to support our understanding of teachers’ confidence to incorporate engineering into their lessons plans and how their confidence changed over time. Noteworthy, our student data analysis resulted in an instrument change for the third year; however due to COVID, pre and post data was limited to schools who taught on a semester basis. Throughout the project we have utilized the ITEST STEM Workforce Education Helix model to support a pragmatic approach of our research informing our practice to enable an “iterative relationship between STEM content development and STEM career development activities… within the cultural context of schools, with teachers supported by professional development, and through programs supported by effective partnerships.” For example, over the course of the project, scaffolding from the University leading interventions to teachers leading interventions occurred. 

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