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1. High-Impact Teaching Practices in Higher Education: Understanding Barriers, Concerns, and Obstacles to Their Adoption

   https://doi.org/10.3390/higheredu3010006  

   VanWyngaarden, Kristin; Pelton, Julie A.; Oquendo, Pamela Martínez; Moore, Christopher (March 2024, Trends in Higher Education)

   This research explores the barriers, concerns, and obstacles undergraduate STEM educators face when implementing high-impact teaching practices (HIPs), the application of which may improve student learning outcomes. Because our study took place during the COVID-19 pandemic, our results also shed light on the unique challenges of utilizing HIPs in asynchronous online-learning environments. Thirteen undergraduate instructors were interviewed about their current teaching practices in order to identify barriers to or support for adopting HIPs. Data collected through semi-structured interviews revealed administrative and financial restraints as barriers to effective teaching which have been found in previous research. A number of new and unique obstacles emerged out of teaching remotely or online during the pandemic, including a heightened concern over the instructor’s ability to connect with students and engage in the best teaching practices. This research extends our current understanding of barriers and concerns about adopting HIPs in undergraduate STEM courses because of the unique perceived threats that emerged during the pandemic. We identify strategies to equip faculty with the support they need to provide equitable learning experiences, including access to consultants who support curriculum development and implementation in the classroom, ongoing educational coaching, and increased access to professional-development opportunities and a community of inquiry to discuss teaching strategies. 

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2. Identified Challenges from Faculty Teaching at Predominantly Undergraduate Institutions after Abrupt Transition to Emergency Remote Teaching during the COVID-19 Pandemic

   https://doi.org/10.3390/educsci11090556  

   Colclasure, Blake C.; Marlier, AnnMarie; Durham, Mary F.; Brooks, Tessa Durham; Kerr, Mekenzie (September 2021, Education Sciences)

   COVID-19 has been one of the most significant disruptors of higher education in modern history. Higher education institutions rapidly transitioned to Emergency Remote Teaching (ERT) in mid-to-late March of 2020. The extent of COVID-19’s impact on teaching and learning, and the resulting challenges facilitating ERT during this time, likely varied by faculty, institutional, and geographical characteristics. In this study, we identified challenges in teaching and learning during the initial transition to ERT at Predominantly Undergraduate Institutions (PUIs) in the Midwest, United States. We conducted in-depth interviews with 14 faculty teaching at Midwestern PUIs to explore their lived experiences. We describe the most overarching challenges related to faculty teaching through four emergent themes: pedagogical changes, work-life balance, face-to-face interactions, and physical and mental health. Five themes emerged that we used to describe the most overarching challenges related to students and their learning: learning patterns, technology access, additional responsibilities, learning community, and mental health. Based upon the identified challenges, we provide broad recommendations that can be used to foster a more successful transition to ERT in unforeseen regional or global crises in the future. 

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3. CHARACTERIZATION OF UNDERGRADUATE BIOLOGY INSTRUCTORS’ GOALS AND STRATEGIES FOR IMPLEMENTING QUANTITATIVE REASONING

   Khushal, Anum (August 2025, University of Nebraska Digital Commons)

   Quantitative reasoning (QR) is the ability to apply mathematics and statistics in the context of real-life situations and scientific problems. It is an important skill that students require to make sense of complex biological phenomena and handle large datasets in biology courses and research as well as in professional contexts. Biology educators and researchers are responding to the increasing need for QR through curricular reforms and research into biology education. This qualitative study investigates how undergraduate biology instructors implement QR into their teaching. The study used pedagogical content knowledge (PCK) and a QR framework to explore instructors’ instructional goals, strategies, and perceived challenges and affordances in undergraduate biology instruction. The participants included 21 biology faculty across various institutions in the United States, who intentionally integrated QR in their instruction. Semi-structured interviews were used to collect data focusing on participants’ beliefs, experiences, and classroom practices. Findings indicated that instructors adapt their QR instruction based on course level and student preparedness. In lower-division courses, strategies emphasized building foundational skills, reducing math anxiety, and using scaffolded instruction to promote confidence. In upper-division courses, instructors expected greater math fluency but still encountered a wide range of student abilities, prompting a focus on correcting misconceptions in integrating math knowledge and fostering deeper conceptual understanding in biology. Many instructors reported that their personal and educational experiences, especially struggles with math, often shaped their inclusive and empathetic teaching practices. Additionally, instructors’ research backgrounds influenced instructional design, particularly in the use of authentic data, statistical tools, and real-world applications. Instructors’ teaching experiences led to refinement in lesson planning, pacing, and active learning strategies. Despite their efforts, instructors faced both internal and external challenges in implementing QR, including discomfort with teaching math, time limitations, student resistance, and institutional barriers. However, affordances such as departmental support, interdisciplinary collaboration, and curricular flexibility helped to overcome some of these challenges. This study highlights the complex relationships between instructors’ experiences, beliefs, and contextual factors in shaping QR instruction. This calls for professional development that supports reflective practice, builds interdisciplinary competence, and promotes instructional strategies that bridge biology and mathematics and will help instructors design a learning environment that better support students’ development of QR skills. These findings offer valuable guidance for professional development aimed at helping biology instructors incorporate quantitative reasoning into their teaching. Such efforts can better equip students to meet the quantitative demands of modern biology and promote their continued engagement in STEM fields through more inclusive and integrated instructional approaches. 

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4. Lessons Learned: Exploring Effective Student-centered Instructional Practices in Middle and Upper-level Engineering

   https://doi.org/10.18260/1-2--47730  

   Wahed, Shabnam; Pitterson, Nicole; Case, Jennifer; Knight, David; Murzi, Homero (June 2024, ASEE Conferences)

   This lessons learned paper delves into the realm of effective student-centered teaching practices within middle and upper-level engineering classes, with the primary goal of enhancing students' acquisition of disciplinary knowledge. The research is anchored by a central inquiry: what student-centered teaching approaches do exemplary engineering faculty employ to promote knowledge-building in their courses, and how do these approaches align with their beliefs about teaching? To address the research question, the study employed the participatory action research (PAR) methodology, which prioritizes the invaluable input and expertise of participants. A diverse group of participants renowned for their teaching excellence was selected from five departments. A total of ten participants were chosen, and data was collected using a variety of methods, including classroom observations, analysis of course materials, surveys, and focus group discussions. Our observations across various courses have revealed common practices employed by instructors to foster effective learning environments. These practices encompass dynamic and diverse class introductions that utilize strategies like revisiting prior content, storytelling, and addressing student well-being to establish a strong foundation for the session. Throughout the class, instructors consistently maintained student engagement through techniques such as group activities, structured interactions, active problem-solving, and thought-provoking question-and-answer sessions. Visual aids and technology were integral in enhancing content delivery. Instructors also ensured the content was relatable by linking lessons to research findings, relatable examples, and familiar landmarks, grounding theoretical concepts in real-life relevance. Personalized support was a priority, with instructors offering targeted feedback to smaller groups and individual students, including one-on-one sessions for additional assistance. Some instructors introduced unique practices such as debate activities, involving students in decision-making processes, cross-course connections, and specialized problem-solving techniques. These diverse approaches collectively underscore the multifaceted strategies instructors employ to create engaging and effective learning experiences. Another significant initiative undertaken in our study involved organizing a summer workshop that provided a platform for instructors to convene and engage in collaborative discussions regarding their teaching practices and their top five teaching priorities. During this workshop, we also deliberated on the preliminary findings from our data collection. The instructors collectively emphasized the importance of getting students engaged in the learning process. We identified several overarching categories of priorities that held relevance for all instructors, including the establishment of personal relationships with students, the effective organization of course content and class activities, strategies for motivating students, and the integration of course content with real-world applications. During the lightning talk, we will share a comprehensive overview of the study's research findings as well as the importance of student-centered teaching practices in engineering education. 

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5. “What Will I Experience in My College STEM Courses?” An Investigation of Student Predictions about Instructional Practices in Introductory Courses

   https://doi.org/10.1187/cbe.19-05-0084  

   Meaders, Clara L.; Toth, Emma S.; Lane, A. Kelly; Shuman, J. Kenny; Couch, Brian A.; Stains, Marilyne; Stetzer, MacKenzie R.; Vinson, Erin; Smith, Michelle K.; Offerdahl, Erika (December 2019, CBE—Life Sciences Education)

   The instructional practices used in introductory college courses often differ dramatically from those used in high school courses, and dissatisfaction with these practices is cited by students as a prominent reason for leaving science, technology, engineering, and mathematics (STEM) majors. To better characterize the transition to college course work, we investigated the extent to which incoming expectations of course activities differ based on student demographic characteristics, as well as how these expectations align with what students will experience. We surveyed more than 1500 undergraduate students in large introductory STEM courses at three research-intensive institutions during the first week of classes about their expectations regarding how class time would be spent in their courses. We found that first-generation and first-semester students predict less lecture than their peers and that class size had the largest effect on student predictions. We also collected classroom observation data from the courses and found that students generally underpredicted the amount of lecture observed in class. This misalignment between student predictions and experiences, especially for first-generation and first-semester college students and students enrolled in large- and medium-size classes, has implications for instructors and universities as they design curricula for introductory STEM courses with explicit retention goals. 

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