Fidelity of Implementation as a Guiding Framework for Transitioning Research-Based Instructional Practices from On Site to Online.

In this Perspective, we contribute to the Journal of Microbiology & Biology Education special issue "Opportunities and Challenges of Online Instruction-Blurring the Lines Between Online and On-Site Teaching and Learning" by introducing a framework to guide instructors in transitioning from on-site to online instruction. The discipline-based education research community has produced a significant literature base demonstrating the effectiveness of various research-based instructional practices (RBIPs) that support student learning in face-to-face environments. However, little is known about how to transport these practices into the online environment. We introduce fidelity of implementation (FOI) as a framework for considering how to adapt RBIPs for online contexts while maintaining the integrity of the aspects of the practice that are thought to support student learning. We use our own experience responding to the global pandemic to provide rich examples of how FOI was used to anticipate challenges in transitioning online and describe how it was used to adapt an RBIP for online instruction.

Interpret with Caution: COPUS Instructional Styles May Not Differ in Terms of Practices That Support Student Learning.

There is a growing need for valid and reliable measures to monitor the efficacy of undergraduate science, technology, engineering, and mathematics (STEM) reform initiatives. The Classroom Observation Protocol for Undergraduate STEM (COPUS) is a widely used tool originally designed to measure the presence of overt instructor and student behaviors. It has subsequently been used to characterize instruction along a continuum from didactic to student centered, and more recently to categorize instruction into one of three styles. Initiatives focused on professional development often support instructors' progression from didactic to student-centered styles. There is a need to examine COPUS instructional styles in terms of behaviors that research has shown to improve student learning. Formative assessment is a research-based practice that involves behaviors accounted for by the COPUS (e.g., posing a question). We qualitatively compared the formative assessment behaviors in 16 biology class sessions categorized into each of the three COPUS styles. We were unable to detect differences in formative assessment behaviors between the COPUS styles. Caution should be taken when interpreting COPUS data to make inferences about the effects of reform efforts. This study underscores the need for additional measures to monitor national reform initiatives in undergraduate STEM.

Visual Literacy in Bloom: Using Bloom's Taxonomy to Support Visual Learning Skills.

Vision and Change identifies science communication as one of the core competencies in undergraduate biology. Visual representations are an integral part of science communication, allowing ideas to be shared among and between scientists and the public. As such, development of scientific visual literacy should be a desired outcome of undergraduate instruction. We developed the Visualization Blooming Tool (VBT), an adaptation of Bloom's taxonomy specifically focused on visual representations, to aid instructors in designing instruction and assessments to target scientific visual literacy in undergraduate instruction. In this article, we identify the need for the VBT, describe its development, and provide concrete examples of its application to a curriculum redesign effort in undergraduate biochemistry.

Lighten the Load: Scaffolding Visual Literacy in Biochemistry and Molecular Biology.

The development of scientific visual literacy has been identified as critical to the training of tomorrow's scientists and citizens alike. Within the context of the molecular life sciences in particular, visual representations frequently incorporate various components, such as discipline-specific graphical and diagrammatic features, varied levels of abstraction, and spatial arrangements of visual elements to convey information. Visual literacy is achieved when an individual understands the various ways in which a discipline uses these components to represent a particular way of knowing. Owing to the complex nature of visual representations, the activities through which visual literacy is developed have high cognitive load. Cognitive load can be reduced by first helping students to become fluent with the discrete components of visual representations before asking them to simultaneously integrate these components to extract the intended meaning of a representation. We present a taxonomy for characterizing one component of visual representations-the level of abstraction-as a first step in understanding the opportunities afforded students to develop fluency. Further, we demonstrate how our taxonomy can be used to analyze course assessments and spur discussions regarding the extent to which the development of visual literacy skills is supported by instruction within an undergraduate biochemistry curriculum.