RESUMEN
Many biology students struggle to learn about the process of meiosis and have particular difficulty understanding the molecular basis of crossing over and the importance of homologous pairing for proper segregation. To help students overcome these challenges, we designed an activity that uses a newly developed Chromosome Connections Kit® from 3-D Molecular Designs to allow learners to explore meiosis at the molecular level. We took a backwards design approach in constructing an effective classroom activity. We developed evidence-based learning objectives and designed a crossing over activity that targets students' misconceptions and key concepts about meiosis. Assessment questions were designed based on the learning objectives and common student misconceptions. The activity consists of three parts: an interactive introductory video, a model-based activity, and reflection questions. The activity was first beta-tested with a small number of students and revised based on feedback. The revised activity was deployed in a mid-level Cell and Molecular Biology course. Analysis of pre-/post-assessment data from students who completed the activity (n = 83) showed strong learning gains on concepts related to ploidy, homology, segregation, and the mechanism and purpose of crossing over. Additionally, students who participated in the activity outperformed nonparticipants on a Genetics assessment about meiosis the following semester.
Asunto(s)
Meiosis , Estudiantes , Cromosomas/genética , ADN , Humanos , Aprendizaje , EnseñanzaRESUMEN
In order to succeed in biochemistry, students must transfer and build upon their understanding of general chemistry and introductory biology concepts. One such critical area of knowledge is bioenergetics. Student misconceptions around energy and free energy must be addressed prior to learning more advanced topics, such as energy flow in metabolic reactions. In this article, we present a series of active-learning videos with embedded questions to address these crucial topics. This video module achieves the following goals: (1) review fundamental chemistry concepts, (2) introduce concepts of reaction coupling and ATP hydrolysis, and (3) foreshadow more advanced biochemical topics such as metabolism. These videos are offered free of charge as traditional videos through YouTube and as an active-learning video module through an online platform, Edpuzzle. Access to videos is provided at chemed.bu.edu.
Asunto(s)
Biología Celular/educación , Metabolismo Energético , Multimedia , Aprendizaje Basado en Problemas , Humanos , EstudiantesRESUMEN
Protein structure-function is a key concept in biochemistry. We used the perspective of domain-specific problem-solving to investigate students' solutions to a well-defined protein structure-function problem. We conducted think-aloud interviews with 13 undergraduate students and performed qualitative content analysis to examine the differences in the domain-general and domain-specific knowledge among correct and incorrect solutions. Our work revealed that students used domain-general and domain-specific knowledge in their problem solving. We also identified difficulties for students with the amino acid backbone, amino acid categorization, and causal mechanisms of noncovalent interactions. Using the identified difficulties, we make recommendations for the design of instructional materials targeted to improve protein structure-function problem solving in the biochemistry classroom. © 2018 International Union of Biochemistry and Molecular Biology, 46(5):453-463, 2018.
Asunto(s)
Bioquímica/educación , Solución de Problemas , Aprendizaje Basado en Problemas , Proteínas/química , Estudiantes/psicología , Humanos , Conformación ProteicaRESUMEN
This study investigates the role of representational competence in student responses to an assessment of hydrogen bonding. The assessment couples the use of a multiple-select item ("Choose all that apply") with an open-ended item to allow for an examination of students' cognitive processes as they relate to the assignment of hydrogen bonding within a structural representation. Response patterns from the multiple-select item implicate heuristic usage as a contributing factor to students' incorrect responses. The use of heuristics is further supported by the students' corresponding responses to the open-ended assessment item. Taken together, these data suggest that poor representational competence may contribute to students' previously observed inability to correctly navigate the concept of hydrogen bonding. © 2017 by The International Union of Biochemistry and Molecular Biology, 45(5):411-416, 2017.
Asunto(s)
Evaluación Educacional , Heurística , Estudiantes/psicología , Humanos , Enlace de HidrógenoRESUMEN
Enzyme-substrate interactions are a fundamental concept of biochemistry that is built upon throughout multiple biochemistry courses. Central to understanding enzyme-substrate interactions is specific knowledge of exactly how an enzyme and substrate interact. Within this narrower topic, students must understand the various binding sites on an enzyme and be able to reason from simplistic lock and key or induced fit models to the more complex energetics model of transition state theory. Learning to understand these many facets of enzyme-substrate interactions and reasoning from multiple models present challenges where students incorrectly make connections between concepts or make no connection at all. This study investigated biochemistry students' understanding of enzyme-substrate interactions through the use of clinical interviews and a national administration (N = 707) of the Enzyme-Substrate Interactions Concept Inventory. Findings include misconceptions regarding the nature of enzyme-substrate interactions, naïve ideas about the active site, a lack of energetically driven interactions, and an incomplete understanding of the specificity pocket.
Asunto(s)
Bioquímica/educación , Enzimas/metabolismo , Sitios de Unión , Dominio Catalítico , Comprensión , Activación Enzimática , Humanos , Estudiantes , Especificidad por SustratoRESUMEN
Formative assessment has long been identified as a critical element to teaching for conceptual development in science. It is therefore important for university instructors to have an arsenal of formative assessment tools at their disposal which enable them to effectively uncover and diagnose all students' thinking, not just the most vocal or assertive. We illustrate the utility of one type of formative assessment prompt (reading question assignment) in producing high-quality evidence of student thinking (student-generated reading questions). Specifically, we characterized student assessment data using three distinct analytic frames to exemplify their effectiveness in diagnosing student learning in relationship to three sample learning outcomes. Our data will be useful for university faculty, particularly those engaged in teaching upper-level biochemistry courses and their prerequisites, as they provide an alternative mechanism for uncovering and diagnosing student understanding.