Your search keyword '"Christine S. Booth"' showing total 4 results

1. Interactive learning modules with <scp>3D</scp> printed models improve student understanding of protein structure–function relationships

Author

Tomáš Helikar, Rebecca Roston, Michelle Howell, Karin V. van Dijk, Christine S. Booth, Sharmin M. Sikich, and Brian A. Couch

Subjects

Male, Models, Anatomic, Protein Conformation, Computer science, Spatial ability, Teaching method, education, Protein structure function, Biochemistry, Interactive Learning, Structure-Activity Relationship, 03 medical and health sciences, Imaging, Three-Dimensional, Protein structure, Human–computer interaction, Concept learning, Humans, Databases, Protein, Simulation Training, Molecular Biology, 030304 developmental biology, amino acids, undergraduate, 0303 health sciences, 05 social sciences, Educational technology, protein structure-function, Proteins, 050301 education, 3D printing, allosteric regulation, Female, Educational Measurement, 0503 education, model-based learning, molecular visualization, student misconceptions, Education, Medical, Undergraduate, Meaning (linguistics)

Abstract

Ensuring undergraduate students become proficient in relating protein structure to biological function has important implications. With current two-dimensional (2D) methods of teaching, students frequently develop misconceptions, including that proteins contain a lot of empty space, that bond angles for different amino acids can rotate equally, and that product inhibition is equivalent to allostery. To help students translate 2D images to 3D molecules and assign biochemical meaning to physical structures, we designed three 3D learning modules consisting of interactive activities with 3D printed models for amino acids, proteins, and allosteric regulation with coordinating pre- and post-assessments. Module implementation resulted in normalized learning gains on module-based assessments of 30% compared to 17% in a no-module course and normalized learning gains on a comprehensive assessment of 19% compared to 3% in a no-module course. This suggests that interacting with these modules helps students develop an improved ability to visualize and retain molecular structure and function.

Published

2020

2. Student Understanding of DNA Structure–Function Relationships Improves from Using 3D Learning Modules with Dynamic 3D Printed Models

Author

Christine S. Booth, Tomáš Helikar, Karin V. van Dijk, Michelle Howell, Sharmin M. Sikich, Rebecca Roston, and Brian A. Couch

Subjects

3d printed, Computer science, Teaching method, education, Biochemistry, Interactive Learning, Structure-Activity Relationship, 03 medical and health sciences, Human–computer interaction, Humans, Learning, Student learning, Students, Molecular Biology, Biological sciences, 030304 developmental biology, 0303 health sciences, Science instruction, Instructional design, 05 social sciences, 050301 education, DNA, Visualization, Printing, Three-Dimensional, Nucleic Acid Conformation, Comprehension, 0503 education

Abstract

Understanding the relationship between molecular structure and function represents an important goal of undergraduate life sciences. Although evidence suggests that handling physical models supports gains in student understanding of structure-function relationships, such models have not been widely implemented in biochemistry classrooms. Three-dimensional (3D) printing represents an emerging cost-effective means of producing molecular models to help students investigate structure-function concepts. We developed three interactive learning modules with dynamic 3D printed models to help biochemistry students visualize biomolecular structures and address particular misconceptions. These modules targeted specific learning objectives related to DNA and RNA structure, transcription factor-DNA interactions, and DNA supercoiling dynamics. We also designed accompanying assessments to gauge student learning. Students responded favorably to the modules and showed normalized learning gains of 49% with respect to their ability to understand and relate molecular structures to biochemical functions. By incorporating accurate 3D printed structures, these modules represent a novel advance in instructional design for biomolecular visualization. We provide instructors with the materials necessary to incorporate each module in the classroom, including instructions for acquiring and distributing the models, activities, and assessments. © 2019 International Union of Biochemistry and Molecular Biology, 47(3):303-317, 2019.

Published

2019

3. Teaching Metabolism in Upper-Division Undergraduate Biochemistry Courses using Online Computational Systems and Dynamical Models Improves Student Performance

Author

Brian A. Couch, Rebecca Roston, Achilles Rasquinha, Michelle Howell, Ales Saska, Christine S. Booth, Resa M Helikar, Changsoo Song, Sharmin M. Sikich, Karin V. van Dijk, and Tomáš Helikar

Subjects

Male, Computer science, Process (engineering), lac operon regulation, General Essays and Articles, education, Sexism, biological systems, Affect (psychology), Biochemistry, General Biochemistry, Genetics and Molecular Biology, Education, 03 medical and health sciences, learning modules, Gender bias, Humans, Learning, Learning gain, Cognitive skill, Students, 030304 developmental biology, 0303 health sciences, Teaching, 05 social sciences, Educational technology, 050301 education, Articles, Test (assessment), Dynamic models, Metabolic regulation, Female, Comprehension, 0503 education

Abstract

Understanding metabolic function requires knowledge of the dynamics, interdependence, and regulation of metabolic networks. However, multiple professional societies have recognized that most undergraduate biochemistry students acquire only a surface-level understanding of metabolism. We hypothesized that guiding students through interactive computer simulations of metabolic systems would increase their ability to recognize how individual interactions between components affect the behavior of a system under different conditions. The computer simulations were designed with an interactive activity (i.e., module) that used the predict-observe-explain model of instruction to guide students through a process in which they iteratively predict outcomes, test their predictions, modify the interactions of the system, and then retest the outcomes. We found that biochemistry students using modules performed better on metabolism questions compared with students who did not use the modules. The average learning gain was 8% with modules and 0% without modules, a small to medium effect size. We also confirmed that the modules did not create or reinforce a gender bias. Our modules provide instructors with a dynamic, systems-driven approach to help students learn about metabolic regulation and equip students with important cognitive skills, such as interpreting and analyzing simulation results, and technical skills, such as building and simulating computer-based models.

Published

2021

4. Visualizing the Invisible: A Guide to Designing, Printing, and Incorporating Dynamic 3D Molecular Models to Teach Structure–Function Relationships

Author

Brian A. Couch, Christine S. Booth, Tomáš Helikar, Michelle Howell, Karin V. van Dijk, and Rebecca Roston

Subjects

0301 basic medicine, Molecular model, Computer science, Emerging technologies, QH301-705.5, Tips & Tools, 3D printing, instruction, General Biochemistry, Genetics and Molecular Biology, Education, 03 medical and health sciences, Human–computer interaction, active learning, ComputingMilieux_COMPUTERSANDEDUCATION, Biology (General), lcsh:QH301-705.5, lcsh:LC8-6691, General Immunology and Microbiology, lcsh:Special aspects of education, LC8-6691, business.industry, 05 social sciences, Structure function, 050301 education, dynamic models, Cell structure and function, Special aspects of education, Structure and function, molecular models, 030104 developmental biology, Dynamic models, lcsh:Biology (General), DNA supercoil, General Agricultural and Biological Sciences, business, 0503 education

Abstract

3D printing represents an emerging technology with significant potential to advance life-science education by allowing students to directly explore the relationship between macromolecular structure and function. In this article and supplemental video guide, we describe our development of a model-based instructional module on DNA supercoiling and outline practical tips for implementing models in undergraduate classrooms. We also present a procedure to design and print 3D dynamic models for classroom use. Furthermore, we describe repositories of 3D biomolecule files to make using models accessible and cost-effective.

Published

2018