key: cord-0072674-j5rgap05 authors: Gary Reiness, C. title: A Compendium of Rationales and Techniques for Active Learning date: 2020 journal: CBE Life Sci Educ DOI: 10.1187/cbe.20-08-0177 sha: fbaddbb79b61298cc76cdf13fbde7dc6b874d248 doc_id: 72674 cord_uid: j5rgap05 A review of Active Learning in College Science, a compendium of techniques for promoting active learning by students, reasons why faculty should adopt active-learning approaches, and suggestions for how to deal with resistance from faculty or students to these approaches. the chapter "Student-Generated Instructional Materials," Coppola and Pontrello provide an instructive overview of the stated topic, but also devote much of the chapter to critiquing several approaches to active learning and defending lecturing and other forms of instructor-centered teaching. This perspective appears to fly in the face of Carl Wieman's (2014) comment that "most STEM courses are still taught by lectures-the pedagogical equivalent of bloodletting," which the editors quote in the preface. In fact, Coppola and Pontrello explicitly reject Wieman's comparison and take exception to some of the other conclusions of Wieman and Eric Mazur. They dislike the term "evidence-based practices," which is in the book's title, and caution against overreliance on concept inventories to assess student learning. They assert that most DBER is designed to verify that an active-learning approach is preferable to lecturing rather than to gather data about who does or does not benefit from these approaches and under what circumstances. They object to the assumptions that underpin "scientific teaching" (Handelsman et al., 2007) , grounding their position in an extensive review of literature, including many sources not commonly found in DBER publications. This chapter is provocative in the best sense of motivating one to reconsider one's assumptions about educational practices. Because most of the other authors in this volume embrace viewpoints and strategies that Coppola and Pontrello criticize, I found myself wishing that the volume had contained a more direct dialogue among authors who hold different positions about the value of active learning. The chapters also vary widely in their intent, with some endeavoring to reach a wide range of readers and others framed with narrower focus, such as applying a technique to a single STEM discipline. For example, in "Clickers in the Biology Classroom," Smith and Knight provide extensive advice about effective practices in employing clickers that will be useful for any STEM educator. Conversely, the chapter "Gamification in General Chemistry" describes how using a computer game that teaches basic chemical concepts (stoichiometry, balancing equations) affects student learning; it will mostly interest chemists. In the chapters that describe studies of the impact of introducing some active-learning strategy on student outcomes, some provide extensive context, essentially a literature review, for their work, along with describing the results of an intervention (such as the chapter on "Investigative Science Learning Environment: Learn Physics by Practicing Science"). Others focus more narrowly on the results of a single study. I found the most valuable chapters to be those that provide a broad overview of a topic or identify general principles that should guide implementation of a particular strategy whatever the reader's discipline or institution type; these constitute about 25 of the 61 chapters. As is typical for a multiauthor volume, there is considerable variation in the quality of the contributions; the writing ranges from excellent and engaging to serviceable. There is also great deal of redundancy in the literature discussed as well as some surprising omissions. Although the volume provides an extensive overview of a large number of active-learning strategies, it is not comprehensive. For example, the peer instruction method developed by Eric Mazur (1997) and colleagues at Harvard is described in several chapters, and an entire chapter by Varma-Nelson and Cracolice is devoted to peer-led team learning. The strategy of team-based learning (Michaelson et al., 2008) is extensively and clearly detailed in a chapter by Leupen, who provides guides and resources (books, annual training workshops) for anyone interested in adopting that approach. On the other hand, the widely used process-oriented guided inquiry learning strategy is mentioned only twice and not described in detail anywhere. Resources such as BioQUEST and the Summer Institutes on Scientific Teaching are not mentioned at all. Several authors note the importance of helping students develop their metacognitive skills, yet there is no explicit discussion of how to do that in any chapter, nor any mention of a well-known resource for teaching metacognition (McGuire and McGuire, 2015) . The book lacks an index, and the chapter titles do not always reflect chapter content. Thus, readers may have to invest some effort to locate particular topics of interest to them and should peruse chapters that, at first glance, may seem less relevant to them. For instance, the chapter by Coppola and Pontrello noted earlier is at least as much about challenging the assumptions of some advocates for active learning as it is about the stated title. A chapter by Linton entitled "Peer Interaction in Active Learning Biology" is noteworthy for providing detailed information about how to construct collaborative student work groups effectively (appropriate group size, demographic composition, etc.) that will be useful to any STEM educator interested in collaborative learning, not only biologists. Beyond these quibbles, there are two noteworthy omissions that, in my view, diminish the value of the book. The first is an insufficient attention to diversity, equity, and inclusion. Only two chapters are devoted explicitly to diversity and universal design for inclusion (chapters 54 by Ballen and 59 by Google and colleagues). A few other chapters discuss the impact of active-learning pedagogies on diversity in STEM, but the issue is not addressed in most chapters and the theme of equity and inclusion is not woven throughout the volume. It is well documented that students whom David Asai terms "science PEERs" (persons excluded because of their ethnicity or race)-particularly African-American, Native-American, and Latinx students-leave science majors at much higher rates than other students (Asai, 2020) . Although there are multiple citations to the work of Freeman et al. (2014) and Eddy and Hogan (2014) documenting the effectiveness of active learning for reducing these disparities, it was surprising that more chapters did not address to what extent and in what circumstances particular strategies can promote equity and inclusion. A second shortcoming is that many of the strategies described in the volume are expensive to implement, in time or other resources, and insufficient attention is paid to how they can be adopted by overextended faculty at institutions with few resources. The editors note in their preface that the book is intended for "thousands of dedicated faculty and graduate students who teach undergraduate science at community and technical colleges, 4-year liberal arts institutions, comprehensive regional campuses, and flagship research universities." However, it seemed to me that the 127 authors, who are predominantly affiliated with doctoral or comprehensive master's-granting universities, were primarily addressing an audience of STEM educators at institutions like their own. Doctoral and master's institutions constitute about a quarter of all U.S. institutions of higher education and enroll just over half the undergraduate students (Center for Postsecondary Research, 2018) . The remaining three-fourths of institutions, enrolling nearly 50% of undergraduates, are baccalaureate colleges, associate's (2-year) colleges, special focus 2-and 4-year colleges (such as art schools), and tribal colleges. In particular, community colleges enroll between a third to more than 40% of undergraduates, including up to half of Latinx and African-American undergraduates; about 70% of community college students come from families with incomes under $50,000 (in 2015-16) (Community College Research Center, n.d.). Despite enrolling a disproportionate fraction of the undergraduate students from low-income families and underserved racial and ethnic groups, community colleges are often overlooked in education research (Schinske et al., 2017) , and community college faculty do not seem to be the intended audience for this volume. As I was reading chapters that recommended involving graduate teaching assistants or undergraduate learning assistants, drawing on teaching and learning centers, acquiring internal or external grant support to launch a reform initiative, or remodeling classrooms to include the latest technology, I could not help but wish they had also offered advice to instructors who had access to none of those resources about how they also could implement active-learning strategies. Students at community colleges or poorly resourced 4-year colleges deserve the same inclusive, efficacious STEM education as those at larger and richer institutions, especially if we are serious about improving the diversity of the scientific community. It is possible for a single faculty member or small group of colleagues to adopt active-learning strategies economically, and I wish there had been more attention given to this. To be fair, some chapters identify tools or strategies that need not cost much in money or time. An excellent chapter by Kiste on implementing a "studio" approach to general chemistry was noteworthy, because it provided very explicit information about how his university changed from lecture to studio-style pedagogy and improved student learning. He also addressed how faculty and staff workloads and the need for other resources were affected (not much). However, most chapters seemed to be written with the assumption that instructors who wished to adopt particular strategy would have access to equivalent resources. I doubt this was true even before budgetary restrictions caused by the Covid-19 pandemic were imposed, and it is certainly not true now. In short, I had hoped to see a more direct consideration of how instructors can do right by students even when resources are limited. Despite these concerns, this book is sufficiently worthwhile to justify its addition to a college or university library or teaching and learning center (assuming an institution has one), although I do not think it is suitable for a personal library. I recommend getting the ebook rather than the print edition, because it is less expensive and the Find function mitigates the absence of an index. I do not recommend reading this book of 61 chapters and more than 1000 pages from beginning to end. Instead, I suggest reading the first five chapters carefully for their focus on why active learning matters and then reading the last section (Chapters 54-61, except 57) for its focus on the principles for effectively implementing active-learning strategies. Doing this should persuade the "skeptical but open-minded readers" to employ active-learning pedagogies or nudge those already favorably inclined to add other tools to their teaching. The remaining chapters then offer many examples of effective strategies that are applicable to most any STEM discipline. Readers can home in on those that seem most relevant to their personal or institutional situation while reserving the others for perusal if time allows. In producing this volume, Mintzes and Walters have provided a helpful resource for STEM educators. Race matters Community college FAQs Getting under the hood: How and for whom does increasing course structure work? CBE-Life Sciences Education Active learning increases student performance in science, engineering, and mathematics Scientific teaching Levers for change: An assessment of progress on changing STEM instruction Peer instruction: A user's manual Teach students how to learn: Strategies you can incorporate in any course to improve student metacognition, study skills, and motivation Teambased learning for health professions education Broadening participation in biology education research: Engaging community college students and faculty Large-scale comparison of science teaching methods sends clear message Bierzychudek and Jenny McFarland for their insightful comments on earlier drafts of this review.