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1. A Professional Development Model to Integrate Computational Thinking Into Middle School Science Through Codesigned Storylines

   Biddy, Q.; Gendreau Chakarov, A.; Bush, J.; Hennessy Elliott, C.; Jacobs, J.; Recker, M.; Sumner, T.; Penuel, W. (March 2021, Contemporary issues in technology and teacher education)

   This article describes a professional development (PD) model, the CT-Integration Cycle, that supports teachers in learning to integrate computational thinking (CT) and computer science principles into their middle school science and STEM instruction. The PD model outlined here includes collaborative design (codesign; Voogt et al., 2015) of curricular units aligned with the Next Generation Science Standards (NGSS) that use programmable sensors. Specifically, teachers can develop or modify curricular materials to ensure a focus on coherent, student-driven instruction through the investigation of scientific phenomena that are relevant to students and integrate CT and sensor technology. Teachers can implement these storylines and collaboratively reflect on their instructional practices and student learning. Throughout this process, teachers may develop expertise in CT-integrated science instruction as they plan and use instructional practices aligned with the NGSS and foreground CT. This paper describes an examination of a group of five middle school teachers’ experiences during one iteration of the CT-Integration Cycle, including their learning, planning, implementation, and reflection on a unit they codesigned. Throughout their participation in the PD, the teachers expanded their capacity to engage deeply with CT practices and thoughtfully facilitated a CT-integrated unit with their students. 

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2. Integrating computational thinking into middle school science through co-designed storylines

   Biddy, Q.; Gendreau Chakarov, A.; Jacobs, J.; Recker, M.; Sumner, T.; Penuel, W. (January 2020, Association for Science Teacher Education)

   We describe a professional development model that supports teachers to integrate computational thinking (CT) and computer science principles into middle school science and STEM classes. The model includes the collaborative design (co-design) (Voogt et al., 2015) of storylines or curricular units aligned with the Next Generation Science Standards (NGSS Lead States, 2013) that utilize programmable sensors such as those contained on the micro:bit. Teachers spend several workshops co-designing CT-integrated storylines and preparing to implement them with their own students. As part of this process, teachers develop or modify curricular materials to ensure a focus on coherent, student driven instruction through the investigation of scientific phenomena that are relevant to the students and utilize sensor technology. Teachers implement the storylines and meet to collaboratively reflect on their instructional practices as well as their students’ learning. Throughout this cyclical, multi-year process, teachers develop expertise in CT-integrated science instruction as they plan for and use instructional practices that align with three dimension science teaching and foreground computational thinking. Throughout the professional learning process, teachers alternate between wearing their “student hats” and their “teacher hats”, in order to maintain both a student and teacher perspective as they co-design and reflect on their implementation of CT-integrated units. This paper illustrates two teachers’ experiences of the professional development process over a two-year period, including their learning, planning, implementation, and reflection on two co-designed units. 

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3. Evaluating the Effectiveness of an Online Professional Development for Rural Middle-School Science Teachers

   https://doi.org/10.1080/1046560X.2023.2287321  

   Moore, Brooke A.; Legleiter, Earl F.; Owens, Kylia; Packard, Brynne; Wright, Jessica (November 2023, Journal of Science Teacher Education)

   In rural, geographically dispersed school districts, access to high-quality face-to-face professional development (PD) is challenging. Our study developed and compared the effectiveness of an online PD for middle-school science teachers working in remote, rural areas of Kansas with an evidence-based traditional face-to-face PD. Fifteen rural middle-school science teacher participants were randomly selected to participate in the online or traditional PD, then taught the Toward High School Biology curriculum to their 504 middle-school students. Findings aligned with our hypothesis that online PD is as effective as traditional in improving student content knowledge. Teachers’ instructional practices in using Next Generation Science Standards improved, as did their use of student-centered instruction and making science relevant to the lives of their students. 

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4. "Making" Science Relevant for the 21st Century: Early Lessons from a Research-Practice Partnership

   https://doi.org/10.1145/3311890.3311910  

   Fancsali, Cheri; Mirakhur, Zitsi; Klevan, Sarah; Rivera-Cash, Edgar (March 2019, FabLearn 2019 proceedings)

   The Maker Partnership Program (MPP) is an NSF-supported project that addresses the critical need for models of professional development (PD) and support that help elementary-level science teachers integrate computer science and computational thinking (CS and CT) into their classroom practices. The MPP aims to foster integration of these disciplines through maker pedagogy and curriculum. The MPP was designed as a research-practice partnership that allows researchers and practitioners to collaborate and iteratively design, implement and test the PD and curriculum. This paper describes the key elements of the MPP and early findings from surveys of teachers and students participating in the program. Our research focuses on learning how to develop teachers’ capacity to integrate CS and CT into elementary-level science instruction; understanding whether and how this integrated instruction promotes deeper student learning of science, CS and CT, as well as interest and engagement in these subjects; and exploring how the model may need to be adapted to fit local contexts. Participating teachers reported gaining knowledge and confidence for implementing the maker curriculum through the PDs. They anticipated that the greatest implementation challenges would be lack of preparation time, inaccessible computer hardware, lack of administrative support, and a lack of CS knowledge. Student survey results show that most participants were interested in CS and science at the beginning of the program. Student responses to questions about their disposition toward collaboration and persistence suggest some room for growth. Student responses to questions about who does CS are consistent with prevalent gender stereotypes (e.g., boys are naturally better than girls at computer programming), particularly among boys. 

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5. Board 298: Supporting Elementary Engineering Instruction in Rural Contexts Through Online Professional Learning and Modest Supports

   https://doi.org/10.18260/1-2--46874  

   Hammack, Rebekah; Robinson, Julie; Boz, Tugba; Lee, Min Jung; Summers, Ryan; Iveland, Ashley; Inouye, Martha; Macias, Meghan; Zaman, Maria; Galisky, John; et al (June 2024, ASEE Conferences)

   Despite the intent to advance engineering education with the NGSS, teachers across all grade levels lack confidence in their engineering content knowledge and pedagogy (Hammack & Ivey, 2019). This dilemma is exacerbated by a lack of quality NGSS-aligned curricular materials that integrate science and engineering at the elementary grades— currently, only one elementary unit reviewed by Achieve has received an NGSS Design Badge that includes engineering (NextGenScience, 2020), and these materials are especially unavailable in schools serving high-needs students (Banilower, 2019). Implementation research now acknowledges that contexts and conditions can, and often do, affect the enactment of innovations and that “improving education requires processes for changing individuals, organizations, and systems” (Century & Cassata, 2016, p. 172). Due to geographic location and, often, smaller collegial networks of teachers who teach science, and engineering, rural schools encounter acute challenges in recruiting and retaining teachers (Arnold et al., 2005) and providing content-specific Professional Learning (PL) (Harmon & Smith, 2007). The goal of this NSF DRK12 multi-institution project is to longitudinally investigate the impacts, sustainability, and costs of NGSS implementation, especially in rural contexts. Our approach differs from most interventions in that it is tailored to rural educators in grades 3–5 and offers curriculum-agnostic, fully online PL that supports teachers in utilizing resources and phenomena found in their local contexts to develop and implement engaging, NGSS-aligned engineering instruction. Our intervention began with a five-day (i.e., weeklong) online PL experience in the summer of 2023 for grades 3–5 teachers in each of four western states. Examples of PL sessions provided include: (1) an overview of three-dimensional learning and phenomena-based instruction; (2) a deep dive into the NGSS Science and Engineering Practices (SEPs); (3) instructional practices that encourage equitable student participation and epistemic agency; and (4) building understanding and comfort with NGSS-aligned engineering and design-based instruction for the elementary grades. The initial intensive PL experience had immediate positive impacts on grades 3–5 teachers’ attitudes and efficacy for teaching engineering. We are now exploring how modest supports influence the sustainability of these changes. Over the 2023-2024 academic year, we are providing teachers with a menu of modest supports including: three 90-minute-long online PL meetings each semester, materials for teaching a locally focused engineering design task, and access to a variety of electronic supports (e.g., Google Classroom Site, shared resources). The fall semester online meetings have focused on supporting teachers to identify connections to science and engineering in their school’s community and how to develop NGSS-aligned engineering design tasks that connect to their local communities. Teachers will be implementing their engineering lessons during December 2023 and January 2024. 

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