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IntroductionThe benefits of actively engaging students is especially relevant for teaching undergraduate students about evolutionary processes and content. Examining eco-immunological data can help students overcome the naïve conception that humans are not evolving or affected by evolutionary pressures. MethodsHere, we used graphical reasoning in two evolution courses (small/honors and large/regular) to teach students about eco-immunology in humans and non-human organisms during a unit on the evolution of life-history traits. The module challenged students to (i) distinguish between immunological and evolutionary fitness, (ii) evaluate graphical data from the primary scientific literature on energy allocation and trade-offs, and (iii) integrate these proximate and ultimate processes into a more wholistic understanding of on-going human evolution. Student performance and perceptions were measured through closed and open response items. Open response items were thematically analyzed to identify salient themes. ResultsStudent performance in the large class increased significantly on items related to fitness, energy trade-offs, and graphical reasoning, while student performance in the small class increased just for items related to energy trade-offs. Student confidence in graphical reasoning, perceptions of the importance of graphical reasoning, and perceptions of the value of interdisciplinary research was high for both classes. Student narrative examples regarding confidence, perceptions of graphical reasoning, and perceptions of interdisciplinary research are presented. DiscussionWe conclude that students can increase their performance and perceptions of eco-immunology and graphical reasoning through an active learning, graph reading module. Furthermore, students can be introduced to the field of immunology through their evolution courses. 

Textbooks are essential resources for developing immunological literacy. This article emphasizes expanding educational focus beyond traditional technical content to more broadly encompass inclusion and equity in the classroom. Equitable and inclusive teaching requires thoughtful selection of course materials by applying principles of inclusion, diversity, equity, and accessibility (IDE-A), yet clear guidance using these principles for course design, especially in textbook selection, is limited. To address this gap, the authors developed and tested the IDE-A rubric and assessed a sample of immunology textbooks, widely used at both undergraduate and graduate levels, to evaluate the rubric’s utility. Each textbook was rated on the overall commitment to the principles of the IDE-A framework, assessing the extent to which the textbook authors and publishers make a concerted effort to address these principles in the introduction, preface, and/or overall framing of the content. Inclusion and diversity were evaluated by examining evidence of stereotype threat, including the use of names in case studies and questions, the selection of textbook imagery, and how diverse representations, perspectives, and voices were acknowledged and incorporated into descriptions of concepts and historical context. Equity and accessibility were assessed by evaluating availability of textbooks and ancillary materials at no cost or reduced price, availability of multiple textbook formats, and publisher’s provision of accessible versions. Furthermore, the rubric could help instructors maintain diversity within STEM fields. This study is one of the first structured evaluations thatapplyIDE-A principles in textbook selection, demonstrating how looking “beyond the microscope” creates more inclusive learning environments. 

The impact of immunology on our daily lives is growing every year. From vaccines to immunotherapies, it's essential for our healthcare professionals (present and future) and the general public as patients or caregivers to be literate in immunology. One way to foster immune literacy in this rapidly advancing field is through Primary Scientific Literature (PSL). There are unique challenges with integrating PSL into immunology courses. First, the laboratory techniques used are often new and not things students have tried before or may have access to, such as flow cytometry. Second, the tools used in this literature can be confusing. For example, antibodies are often used as both part of the research method and as the research subject. Third, immunology literature is especially heavy in acronyms, jargon and abbreviations. In this manuscript, four instructors gathered to discuss the strategies that they have used in their classrooms to utilize PSL in immunology (PSL-I) and scaffold various activities around it. These teaching methods vary from highlighting immunology-specific techniques, interpreting figures, alignment with the 5E instructional model to guide an inquiry, jigsaw format learning, to in-depth journal-club style analysis. Finally, this paper discusses reflections from our experiences teaching PSL-I. We know that there are misconceptions about immunology and health in general. If we teach PSL and how to interpret it, we hope to prepare our students not just for their chosen field, but also to think critically and discern facts from fiction in society. 

Training students in interdisciplinary thinking is critical for the future of scientific discovery and problem-solving more generally. Therefore, students must have early opportunities to grapple with knowns and unknowns at the frontiers of interdisciplinary inquiry. Neuroimmunology challenges students to think at the intersection of two rapidly evolving fields, neuroscience and immunology. As these disciplines focus on complex systems, their intersection represents a unique opportunity for students to witness the nature and process of interdisciplinary collaboration and synthesis. However, the fast pace of research and specialized knowledge in both disciplines present challenges for instructors interested in teaching the subject to undergraduate students. In this article, we share and describe a curriculum developed using a backward-design approach to analyze core concepts in both neuroscience and immunology, which were articulated by disciplinary experts in collaboration with their respective education communities. We determine overlaps between these conceptual frameworks, identify key prerequisite knowledge, and suggest example activities to introduce neuroimmunology to undergraduate students. This curriculum may be used for an entire course, or modified into shorter units that instructors can use within diverse educational contexts. We hope that this effort will encourage instructors to adopt neuroimmunology into their curricula, provide a roadmap to forge other such interdisciplinary educational collaborations, and prepare students to develop creative solutions to current and future societal problems. 

ABSTRACT Collaboration and communication are important competencies for undergraduate life science education, as noted in theVision and Change in Undergraduate Biology Educationreport. However, initiating collaboration and communication in the classroom can be an anxiety-inducing experience for many students. In contrast to traditional-style icebreakers, we introduce a course content-focused icebreaker activity that served as a group-forming undertaking on the first day of class. We developed four sets of handouts (icebreaker tickets), each having a common course theme (e.g., microbiology, cell biology, physiological system infections/disorders, virology). Students were randomly provided with a ticket at the beginning of the course, and they worked to establish groups with their peers, based on their own interpretation of the ticket’s content and rationalization of a grouping scheme. Student feedback and engagement data collected from implementation at three independent institutions were largely positive, where students reported the activity to be an effective tool for building a course content-focused community of learners. The icebreaker tickets and instructor’s notes disseminated in this manuscript can be adapted to fit educators’ course goals and help set the tone for the first day of the class and beyond that fosters communication and collaboration among students. 

Immune literacy garnered significant attention in recent years due to the threat posed by emerging infectious diseases. The pace of immunological discoveries and their relevance to society are substantial yet coordinated educational efforts have been rare. This motivated us to create a task force of educators to reflect on pedagogical approaches to teaching immunology and to draft, develop, and evaluate key competencies for undergraduate immunology education. The research questions addressed include: 1) Which competencies are considered important by educators? 2) Are the illustrative skills clear, accurate and well aligned with the core competencies listed in theVision and Changereport?; 3) What are the concerns of immunology educators about competencies and skills? We collected data on the draft competencies using surveys, focus groups, and interviews. The iterative revision phase followed the community review phase before finalizing the framework. Here, we report a hierarchical learning framework, with six core competencies, twenty illustrative skills, and companion immunology-specific example learning outcomes. Predominant themes from interviews and focus groups, which informed revisions of this framework are shared. With the growing need for immunology education across the sciences, the ImmunoSkills Guide and accompanying discussion can be used as a resource for educators, administrators and policymakers. 

Abstract One challenge in the teaching of immunology is the complexity of the subject. Immunology presents a long list of unique cells, signaling molecules, receptor-ligand interactions, regulatory mechanisms, developmental pathways, and outcomes that can feel burdensome to instructors and unapproachable to students. The beauty of this subject, however, is that these unique features interact in networks that parallel those in other biological fields. Visualizing the interactions between tissues, cells, and molecules of the immune system and their outcomes can promote immunological literacy and a broad understanding of biological systems. Cell Collective (cellcollective.org) is an open-access, approachable software system that allows students and researchers alike to build models and perform simulations of biological processes. Students can use this interactive platform to probe cell-cell interactions, signaling pathways, metabolic networks, etc. while building systems thinking and computational skills, which are critical for success in STEM fields. After building models, real-time simulations can be run to visualize and understand the dynamics of the biological system under conditions of environmental pressure, disease, mutation, etc. Instructors can assess student knowledge by building assessments into modules in a formative or summative manner. Because it is free, user-friendly, and offers a host of pre-built training, educational and experimental modules, Cell Collective is ideally suited for use in all types of educational settings. Supported by a grant from the NSF (RCN-UBE) 2120806 

ABSTRACT During the COVID-19 pandemic, biology educators were forced to think of ways to communicate with their students, engaging them in science and with the scientific community. For educators using course-based undergraduate research experiences (CUREs), the challenge to have students perform real science, analyze their work, and present their results to a larger scientific audience was difficult as the world moved online. Many instructors were able to adapt CUREs utilizing online data analysis and virtual meeting software for class discussions and synchronous learning. However, interaction with the larger scientific community, an integral component of making science relevant for students and allowing them to network with other young scientists and experts in their fields, was still missing. Even before COVID-19, a subset of students would travel to regional or national meetings to present their work, but most did not have these opportunities. With over 300 million active users, Twitter provided a unique platform for students to present their work to a large and varied audience. The Cell Biology Education Consortium hosted an innovative scientific poster session entirely on Twitter to engage undergraduate researchers with one another and with the much broader community. The format for posting on this popular social media platform challenged students to simplify their science and make their points using only a few words and slides. Nineteen institutions and over one hundred students participated in this event. Even though these practices emerged as a necessity during the COVID-19 pandemic, the Twitter presentation strategy shared in this paper can be used widely. 

ABSTRACT Course-based undergraduate research experiences (CUREs) provide a way for students to gain research experience in a classroom setting. Few examples of cell culture CUREs or online CUREs exist in the literature. The Cell Biology Education Consortium (CBEC) provides a network and resources for instructors working to incorporate cell-culture based research into the classroom. In this article, we provide examples from six instructors from the CBEC network on how they structure their cell-culture CUREs and how they transitioned the labs to online in the spring semester of 2020. We intend for these examples to provide instructors with ideas for strategies to set up cell culture CUREs, how to change that design mid-term, and for creating online CUREs in the future.