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Though Community Asset Mapping (CAM) has been widely used in community-development and applied to public health interventions, little has been done to synthesize the current state of this approach. This paper reports the findings from a scoping review of research where CAM was applied to public health practice and research initiatives. We identified and reviewed 28 articles featuring studies that used asset mapping for public health purposes. Overall, we found that the purpose and methods related to asset mapping varied widely across studies. Given the potential benefits of asset mapping and its relevance to social work principles, researchers and public health professionals should approach asset mapping with the same level of attention, rigor, and ethics as other research methodologies or intervention design. There is an obligation to engage in asset mapping in ways that promote our ethical principles of service, dignity, integrity, and competence. 

In 2020, over 116,000 students took the Advanced Placement Computer Science Principles (AP CSP) Exam. Although Black female students have participated in AP CSP at higher rates than for the AP CSA course, their representation is still disproportionately lower than the school population of Black females. In this Experience Report, we present the early results of an NSF-sponsored effort that provides an AP CSP preparatory experience and CS career awareness to Black female students from rural, urban, and suburban communities in the state of Alabama. At the project’s core is a peer-learning community (PLC) facilitated by Black female teachers with deep knowledge of AP CSP. An intensive summer experience prepares students for the AP CSP course through culturally-responsive, project-based learning experiences designed to connect advanced computing concepts to the students’ personal lives and career aspirations. Interactions and support continue throughout the academic year to facilitate AP exam readiness. Online interactions among the PLC members serve to mitigate the barriers that young women of color typically encounter when pursuing CS education, increasing their persistence and success in CS. We examined whether students’ project participation enhances self-efficacy and perceived competency in CS, increases positive attitudes, awareness, and desire to pursue CS studies and careers, and mitigates perceived socio-cultural barriers to pursue studies and careers in CS. Our initial findings include AP CSP examination qualifying rates (87.5%) that exceed the 2019 national/statewide rates for all subgroups (including Alabama White male students), increased perceptions of Black females as belonging in CS, and gains in computing self-efficacy throughout the academic year. 

The expansion of K-12 computer science (CS) has driven a dramatic need for educators who are trained in CS content and pedagogy [1]. This poster describes our effort to train teacher candidates (i.e., pre-service teachers who are students seeking degrees within a College of Education), who are specializing in secondary mathematics education, to be future CS educators. We specifically describe our collaboration to provide a blended preparatory six-week training for the ETS CS Praxis exam (5652), assisting our pre-service students in satisfying the CS certification requirements in our state before they graduate and begin their professional teaching career. Given the unique challenges of pre-service CS teacher preparation [2], blended models, which combine both in-person and online instruction, are an effective approach to building a pre-service program. Within our pre-service CS program, students first complete a two-course pathway that prepares them in AP CSP content and pedagogy experiences, including observations in local AP CSP classrooms [3]. After completing the two courses, our students participate in the blended version of the WeTeach_CS Praxis preparation course to achieve certification. The in-person support provided by the blended model contributed significantly to certification success in this project. With a cut-score of 149 for the Praxis exam, all 11 of our pre-service students who completed the course received a passing score (including one student with a perfect score of 200, and another student with a 195); the average score for our pre-service students was 175. An additional 11 in-service teachers, with diverse backgrounds in CS content knowledge, also participated in the blended Praxis preparation course, with an average score of 166. Given the unique challenges of pre-service CS teacher preparation, university pre-service CS teacher programs should look to innovative models of teacher support developed by in-service programs to make substantial gains in CS teacher certification. Incorporating an asynchronous online course that allows teachers with a wide range of prior experience in CS to learn at their own pace with in-person coursework and support appears to be a viable model for assisting non-CS major teacher candidates in achieving a CS certification. With the blended model, even teachers with no background knowledge in CS were successful. Within our pre-service CS program, students first complete a two-course pathway that prepares them in AP CSP content and pedagogy experiences, including observations in local AP CSP classrooms [3]. After completing the two courses, our students participate in the blended version of the WeTeach_CS Praxis preparation course to achieve certification. The in-person support provided by the blended model contributed significantly to certification success in this project. With a cut-score of 149 for the Praxis exam, all 11 of our pre-service students who completed the course received a passing score (including one student with a perfect score of 200, and another student with a 195); the average score for our pre-service students was 175. An additional 11 in-service teachers, with diverse backgrounds in CS content knowledge, also participated in the blended Praxis preparation course, with an average score of 166. Incorporating an asynchronous online course that allows teachers with a wide range of prior experience in CS to learn at their own pace with in-person coursework and support appears to be a viable model for assisting non-CS major teacher candidates in achieving a CS certification. With the blended model, even teachers with no background knowledge in CS were successful. 

The surge of interest in K-12 computer science (CS) over the past decade has led to a deep need for a corresponding expansion of trained teachers. The primary focus of most K-12 CS teacher professional development has been for current in-service teachers who have little background in CS. To raise the importance of CS within Colleges of Education, we believe that new pathways and experiences are needed for pre-service Education majors to learn more about authentic CS topics and pedagogy. This experience report summarizes our efforts over the past two years to prepare Secondary Math Education (SEMA) majors to teach AP CS Principles (AP CSP). Our approach consists of the following curricular activities: 1) a two-course sequence, with the first course mapping to the content topics of the AP CSP Curriculum Framework, and the second course consisting of a reflection of CS methods and pedagogy, including opportunities for SEMA students to develop and present their own AP CSP lesson plans; 2) opportunities for SEMA students to observe AP CSP classrooms in local high schools through our partnership with experienced AP CSP teachers; 3) summer participation in a College Board AP Summer Institute for AP CSP, and 4) a six-week ETS Praxis CS preparation modules-based course, offered to both pre-service SEMA students and in-service teachers. We summarize our lessons learned and present results that suggest our approach is preparing pre-service students with pedagogical and content knowledge that meets or exceeds current in-service training models (including an analysis of recent Praxis results for CS certification in our state). 

The Exploring Computer Science (ECS) curriculum provides foundational knowledge of Computer Science (CS) to high school students as a stand-alone course. ECS began in the Los Angeles Unified School District in the late 2000s where it gained eminence for broadening participation in computing (BPC), with Latinx students representing over 70% of enrollment. This experience report describes a partnership that consists of three Universities, dozens of school districts, the ECS team, and other stakeholders to bring the ECS curriculum in mainly rural school districts in Alabama that have a majority African-American student population. Sixty in-service teachers (one teacher per school) have received professional learning opportunities to gain knowledge and skills to teach ECS. Signs of early broader impacts are emerging: 78% of our ECS enrollment are underrepresented minority (URM) students with nearly half of the cohort consisting of female students. Students reported they were engaged in working collaboratively and sharing responsibilities with others. Furthermore, students who reported being more involved in the ECS course had deeper confidence in their ability to succeed in CS, reported greater overall outcomes, had more confidence in development of 21st century skills, found the course more relevant, were more motivated to persist in CS, and exhibited increased interest in CS careers. We provide a comprehensive description of the partnership’s accomplishments and the evaluation findings on student CS experiences and on teacher self-efficacy in ECS preparation and instruction. Our findings contribute to the BPC literature, specifically for schools with predominantly African-American enrollment in rural communities.