Exploring Undergraduate Biochemistry Students' Gesture Production Through an Embodied Framework.

Interpreting three-dimensional models of biological macromolecules is a key skill in biochemistry, closely tied to students' visuospatial abilities. As students interact with these models and explain biochemical concepts, they often use gesture to complement verbal descriptions. Here, we utilize an embodied cognition-based approach to characterize undergraduate students' gesture production as they described and interpreted an augmented reality (AR) model of potassium channel structure and function. Our analysis uncovered two emergent patterns of gesture production employed by students, as well as common sets of gestures linked across categories of biochemistry content. Additionally, we present three cases that highlight changes in gesture production following interaction with a 3D AR visualization. Together, these observations highlight the importance of attending to gesture in learner-centered pedagogies in undergraduate biochemistry education.

An idea to explore: Introduction of "biochemical tales" in medical education-Learning made fun.

Innovations in medical education, including the integration of narrative-based tales, are transforming the way complex biochemical concepts are taught and understood. In this "Idea to Explore", the essence of integrating tales that personify molecules and depict biochemical processes as engaging stories to enhance student engagement, promote active learning, and improve knowledge retention is discussed. It also explores the effectiveness of scientific discovery games and traditional scientific stories in deepening students' interest in biochemistry. Highlighting the potential of narrative methods to make biochemistry more accessible and engaging, educators are encouraged to adopt creative teaching tools that promote critical thinking, problem-solving, and communication skills, thereby inspiring active participation, and lifelong learning in biochemistry.

Blended learning in biochemistry: The development of pre-class and post-class learning aids for electron transport chain and oxidative phosphorylation.

Electron transport chain and oxidative phosphorylation are always a challenging topic for students studying metabolism. We had adopted blended learning in metabolism teaching and evaluated the learning experiences of students. In this project, a pre-class learning aid the Story Mode and a post-class learning aid the Revision Mode in the Powerland was developed that facilitated students learning electron transport chain and oxidative phosphorylation. In the Story Mode, pathways were presented by short animations and simplified diagram that allowed students to understand basic concepts and recall simple facts of the topic. Students were asked to watch the animations before class to acquire lower level of cognitive learning first, and this facilitated students in understanding more complicated concepts later on during class. Another challenge that students faced was that they were especially weak at integrating metabolic pathways and understand the relationships between these pathways. A metro map was designed in the Revision Mode that aided students in knowledge integration, and the functions of biomolecules were summarized in flashcards that helped students in revising the concepts. This interactive self-learning tool was packaged as a courseware using the Articulate Storyline.

A cord of four strands: Perspective of pre-medical and medical students on combined teaching modalities in undergraduate biochemistry.

Despite being a traditional coursework for pre-medical and medical students around the globe, biochemistry education suffers from a lack of positive appreciation due to the nature of the subject combined with deficiency of teaching modalities. A first semester biochemistry course was designed to include four different teaching modalities: lectures, recitations, case studies, and student presentations. A multi-item, anonymous, and voluntary questionnaire was distributed to students who had just completed the course and to those who had taken it the previous year. The questionnaire asked students to evaluate the course and how the different modalities affected their learning. These questionnaires took place in a two-year period between 2020 and 2021. Eighty-six (46%) of 186 total students responded. The vast majority of respondents agreed with the use of multimodal teaching techniques with respect to its impact on overall preparedness for future coursework, understanding, and enjoyability. Lectures and recitations were found to be the most useful in information retention and learning, although the same were found to be less enjoyable than other modalities. Although case studies and presentations were found to be enjoyable, most students ranked them low in terms of information retention and were the most voted to be removed from the course. There was general agreement between premedical and medical students' perception on the usefulness of the multimodal teaching techniques with respect to medical biochemistry modules and standardized exams. The agreement between cohorts suggests the premedical students accurately evaluated the usefulness of the course for the following year and validates the usefulness of the premedical student surveys. Use of multiple modalities in biochemistry education can be of substantial benefit in engaging and preparing students for further education.

CUR(E)ating a new approach to study fungal effectors and enhance undergraduate education through authentic research.

Course-based Undergraduate Research Experiences (CUREs) integrate active, discovery-based learning into undergraduate curricula, adding tremendous value to Biochemistry and Molecular Biology (BMB) education. There are multiple challenges in transforming a research project into a CURE, such as the readiness of students, the time commitment of the instructor, and the productivity of the research. In this article, we report a CURE course developed and offered in the University of Massachusetts Amherst BMB Department since 2018 that addresses these challenges. Our CURE focuses on fungal effectors which are proteins secreted by a destructive pathogenic fungus Fusarium oxysporum, one of the top five most devastating plant pathogens. By studying this group of proteins, students are connected to real-world problems and participate in the search for potential solutions. A 3-week "standard Boot Camp" is implemented to help students familiarize themselves with all basic techniques and boost their confidence. Next, molecular cloning, a versatile technique with modularity and repeatability, is used as the bedrock of the course. Our past 5 years of experience have confirmed that we have developed a novel and feasible CURE protocol. Measurable progress documented by students who took this course includes stimulated active learning and increased career trajectory to pursue hypothesis-based research to address societal needs. In addition, data generated through the course advance ongoing lab research. Collectively, we encourage the implementation of CURE among research-intensive faculty to provide a more inclusive research experience to undergraduate students, an important element in predicting career success.

Evolution of a self-renewing, participant-centered workshop series in BMB assessment.

We present as a case study the evolution of a series of participant-centered workshops designed to meet a need in the life sciences education community-the incorporation of best practices in the assessment of student learning. Initially, the ICABL (Inclusive Community for the Assessment of Biochemistry and Molecular Biology/BMB Learning) project arose from a grass-roots effort to develop material for a national exam in biochemistry and molecular biology. ICABL has since evolved into a community of practice in which participants themselves-through extensive peer review and reflection-become integral stakeholders in the workshops. To examine this evolution, this case study begins with a pilot workshop supported by seed funding and thoughtful programmatic assessment, the results of which informed evidence-based changes that, in turn, led to an improved experience for the community. Using participant response data, the case study also reveals critical features for successful workshops, including participant-centered activities and the value of frequent peer review of participants' products. Furthermore, we outline a train-the-trainer model for creating a self-renewing community by bringing new perspectives and voices into an existing core leadership team. This case study, then, offers a blueprint for building a thriving, evolving community of practice that not only serves the needs of individual scientist-educators as they seek to enhance student learning, but also provides a pathway for elevating members to positions of leadership.

An integrated laboratory work to improve students' practical skills and attitudes toward biochemistry in the biochemistry course.

This research reports on implementing the integrated laboratory work to achieve effective learning in the biochemistry course. The integrated laboratory work includes three stages: pre-laboratory, lab work, and post-laboratory. In other words, the three stages include planning, implementing, and evaluating investigation activities in the laboratory. The research design used was a posttest control group design consisting of a control and an experimental group. There were 67 students as respondents, who were divided into control (N = 33) and experimental (N = 34) groups. Practical skills were measured using an assessment rubric with the involvement of the observer. The categories of practical skills measured were procedural skills, observation skills, interpretation skills, and reporting skills. Attitude toward biochemistry was measured using a questionnaire with five Likert scales. The indicators of attitudes toward biochemistry used were liking for a biochemistry theory lesson, liking for biochemistry laboratory work, evaluative beliefs about biochemistry, and behavioral tendencies to learn biochemistry. The influence of the implementation of the integrated laboratory work on the students' practical skills and attitudes toward biochemistry was analyzed using MANOVA. The research result shows that implementing the integrated laboratory work improves students' average scores in practical skills and attitudes toward biochemistry. All the practical skills and attitudes categories in the experimental group have a higher score than those in the control group. The reason is that the work of the integrated laboratory can prepare students to conduct better investigations in biochemistry laboratory work.

An acceptability study of the introduction of total online or partial online PBL in a large classroom setting in biochemistry.

BACKGROUND: Traditional problem-based learning (PBL) relying on tutored learning in small groups is very resource-intensive. Little is known about the benefits of PBL in a large classroom setting. This paper introduced a PBL case into the traditional didactic biochemistry course and investigated the acceptability of total online or partial online PBL in a large classroom setting introduced during the coronavirus pandemic. METHODS: The students were allocated into either total online Group 1, partial online Group 2, or partial online and with poorer academic performance Group 3. A questionnaire comprising of 8 closed-ended questions and 2 open-ended questions and final exam performances were used to evaluate the acceptability of total online or partial online PBL in a large classroom setting. The 8 closed-ended questions were analysed by the Kruskal-Wallis test or chi-square tests. The word cloud analysis of the 2 open-ended questions were conducted by Wenjuanxing. Students' performances in the final examination were analysed by One-way Anova. RESULTS: Both total online and partial online PBL were rated highly by the students. Overall, there were no significant differences in the effectiveness evaluation of PBL between Group 2 and Group 3. There were no significant differences in final exam performances between Group 1 and Group 2. However, Group 1 rated the effectiveness of PBL much higher than Group 2 and 3. Word cloud analysis of the 2 open-ended questions showed students' positive perspectives of PBL. In biochemistry teaching, from the perspective of the students, the expected optimal number of useful PBL cases might be 2. CONCLUSIONS: Both total online and partial online PBL in a large classroom setting were widely accepted as a beneficial supplement to traditional biochemistry classes.

A project-oriented biochemistry laboratory for protein engineering and structure-function using small laccase enzyme from Streptomyces coelicolor.

An understanding of structure-function relationships in proteins is essential for modern biochemical studies. The integration of common freely accessible bioinformatics tools available online with the knowledge of protein-engineering tools provide a fundamental understanding of the application of protein structure-function for biochemical research. In order for students to apply their prior knowledge of recombinant protein technology into the understanding of protein structure-function relationships, we developed a semester-long project-oriented biochemistry laboratory experience that is the second laboratory course of a series. For easier integration of knowledge and application, we organized this course into four sequential modules: protein structure visualization/modification, mutagenesis target identification, site-directed mutagenesis, and mutant protein expression, purification, and characterization. These tasks were performed on the protein small laccase (SLAC) that was cloned and characterized by students in the previous semester during the first biochemistry laboratory course of the series. This goal-oriented project-based approach helped students apply their prior knowledge to newly introduced techniques to understand protein structure-function relationships in this research-like laboratory setting. A student assessment before and after the course demonstrated an overall increase in learning and enthusiasm for this topic.

Teaching and assessing undergraduate collaboration skills scaffolded through the biochemistry curriculum using collaboration rubrics and student learning contracts.

The Department of Chemistry and Biochemistry at St. Mary's College of Maryland has scaffolded collaboration skills throughout the Biochemistry curriculum and developed several assessment tools to evaluate these skills. Biochemistry I and II have used team contracts at the beginning of extensive team projects where students identify their strengths, review expectations, and plan for group communication. At the conclusion of each project, each student assesses their own contributions and team members for various parts of the project. A common collaboration rubric was also applied in Biochemistry I and II as well as in two other courses, General Chemistry II Lab and Physical Chemistry I Lab, for students to evaluate themself and team members using the following subcategories: quality of work, commitment, leadership, communication, and analysis. In Biochemistry I and II, we used this rubric for multiple assignments that are part of the projects in the lecture courses. In the General Chemistry II Lab, we provided elements of this rubric within an evaluation form that reflects these collaboration attributes after each lab experience, so students can assess and report privately on their experiences as part of their collaboration grade for the course. A similar collaboration rubric is completed by students for each team-based laboratory within Physical Chemistry I. We also demonstrate different ways that instructors can use the data from these assessment tools. In our department, we are using these tools to frame the importance of collaboration skills and collecting data to inform our teaching of these skills. Preliminary data suggest that our curriculum is successfully teaching students how to be good collaborators.

Evaluating the effectiveness of a new student-centred laboratory training strategy in clinical biochemistry teaching.

BACKGROUND: The error-proneness in the preanalytical and postanalytical stages is higher than that in the analytical stage of the total testing process. However, preanalytical and postanalytical quality management has not received enough attention in medical laboratory education and tests in clinical biochemistry courses. METHODS/APPROACH: Clinical biochemistry teaching program aim to improve students' awareness and ability of quality management according to international organization for standardization 15,189 requirements. We designed a student-centred laboratory training program, according to case-based learning that included 4 stages: "establish an overall testing process based on the patient's clinical indicator, clarify principles, improve operational skills, and review process and continuous improvement". The program was implemented in our college during the winter semesters of 2019 and 2020. A total of 185 undergraduate students majoring in medical laboratory science participated in the program as a test group, and the other 172 students were set up as the control group and adopted the conventional method. The participants were asked to finish an online survey to evaluate the class at the end. RESULTS/OUTCOMES: The test group had significantly better examination scores not only in experimental operational skills (89.27 ± 7.16 vs. 77.51 ± 4.72, p < 0.05 in 2019 grade, 90.31 ± 5.35 vs. 72.87 ± 8.41 in 2020 grade) but also in total examination (83.47 ± 6.16 vs. 68.90 ± 5.86 in 2019 grade, 82.42 ± 5.72 vs. 69.55 ± 7.54 in 2020 grade) than the control group. The results of the questionnaire survey revealed that the students in the test group better achieved classroom goals than those in the control group (all p < 0.05). CONCLUSIONS: The new student-centred laboratory training program based on case-based learning in clinical biochemistry is an effective and acceptable strategy compared with the conventional training program.

An idea to explore: Augmented reality and LEGO® brick modeling in the biochemistry and cell biology classroom-two tactile ways to teach biomolecular structure-Function.

We present here two accessible ways for enhanced understanding of complex biological structures and their function in undergraduate Biology and Biochemistry classrooms. These methods can be applied for in-class instruction as well as for remote lessons, as they are cheap, easily available and easy to implement. LEGO® bricks and MERGE CUBE based augmented reality can be applied to make three-dimensional representation for any structure available on PDB. We envisage these techniques to be useful for students when visualizing simple stereochemical problems or complex pathway interactions.

A research-led flexible cell biology practical for biological sciences undergraduate and postgraduate degree courses.

A challenge in the pandemic era is to implement effective but flexible practical teaching for biological sciences courses. Such teaching needs to deliver conceptual, analytical and practical skills training while having the option to rapidly respond to health and safety issues, local regulations, staff and student concerns. In this paper, we describe a set of cell biology practicals (mini-project) that meets many of these requirements and provides flexibility in providing skills training both through online and in practical laboratory environments. We have used a human adenocarcinoma cell line A431 stably transfected with a fluorescent cell cycle reporter as a biological model to deliver training through discrete work packages encompassing cell culture, fluorescence microscopy, biochemistry and statistics. How such work packages can be modified to, an online format either partially or completely is also described. Furthermore, the activities can be adapted for teaching both undergraduate and postgraduate level courses to ensure effective skills training which is applicable to a wide range of biological degree programs and levels of study.

The impact of a story on learning ketone body metabolism.

Biochemistry is a core subject in the cross-disciplinary training on Biotechnology engineering courses. Metabolic pathways teaching has traditionally integrated hands-on laboratory experiences and traditional lectures, which detail a large number of reactions at a molecular level, their enzymes and regulation. The current scenario of Covid-19 outbreak have motivated the development of complementary tools that expand the horizon of metabolism teaching. In this study, we employed a story-based methodology to strengthen the metabolic pathways learning and to measure students' perception. Specifically, a peer-reviewed tale describing the ketone body metabolism was used during five semesters as a didactic strategy to teach this biochemical process. A questionnaire assessed the students' understanding and acceptance of the methodology (n = 83). Our findings showed that a high proportion of students (83.13%) were able to relate the story to the topics studied in the classroom (ketogenesis and ketolysis). On the other hand, they were satisfied and suggested that such methodology is effective and fun. In summary, most of the survey responses related to acceptance of story-based strategy ranged from 72% to 97%. Collectively, these results indicated that the story is appropriate to decomplex pathways, becoming a simple tool for driving motivation, learning and engagement of students. The narrative represents a bridge to connect the intriguing series of chemical reactions involved in the anabolism and degradation of 3-hydroxybutyrate (3-OHB), acetoacetate, and acetone with previously learned knowledge, emotions, and key concepts. In conclusion, the tale was useful to decode ketone body-related pathways and making metabolism learning more interesting and easier.

Abordagem integrativa na prática de bioquímica: do laboratório à clínica / Integrative approach in biochemistry practice from laboratory to clinic

Objetivou-se relatar a experiência de discentes e docentes diante da aplicação de ferramentas de metodologia ativa para a integração dos temas de Bioquímica com os das disciplinas do eixo clínico-profissional. Inicialmente, as subturmas da aula prática foram divididas em equipes de trabalho. Os alunos receberam um protocolo contendo objetivos, princípios gerais e procedimentos na semana anterior à aula prática. Nos dias das aulas de "Preparo de Soluções" e "Capacidade Tamponante", um artigo científico relativo à Odontologia foi entregue para leitura e discussão em grupo. Como atividade prática, as equipes recebiam um desafio relacionado ao artigo e que exigiria aplicação dos objetivos de aula. Esta experiência demonstrou que a metodologia ativa pode funcionar como facilitadora para uma abordagem contextualizada e integrada da Bioquímica, refletindo em maior engajamento e rendimento dos alunos, além de contribuir para um aprendizado significativo (AU).

El objetivo fue relatar la experiencia de estudiantes y profesores en cuanto a la aplicación de herramientas metodológicas activas para la integración de los temas de Bioquímica con los de las disciplinas del eje clínico-profesional. Inicialmente, las subclases de la clase práctica se dividían en equipos de trabajo. Los estudiantes recibieron un protocolo con objetivos, principios generales y procedimientos en la semana anterior a la clase práctica. En los días de las clases de "Preparación de Soluciones" y "Capacidad Amortiguadora", se entregó un artículo científico relacionado con la Odontología para lectura y discusión en grupo. Como actividad práctica, los equipos recibieron un reto relacionado con el artículo y que requería la aplicación de los objetivos de clase. Esta experiencia demostró que la metodología activa puede funcionar como facilitadora de un abordaje contextualizado e integrado de la Bioquímica, reflejándose en un mayor compromiso y desempeño de los estudiantes, además de contribuir al aprendizaje significativo (AU).

The objective was to report the experience of students and professors regarding the application of active methodology tools aimed at integrating Biochemistry themes with those of the disciplines from the clinical-professional axis. Initially, subgroups forthe practical class were divided into work teams. The students received a protocol containing objectives, general principles and procedures the week before the practical class. On the days of the "Preparation of Solutions" and "Buffering Capacity" classes, a scientific article related to Dentistry was delivered for group reading and discussion. As a practical activity, the teams received a challenge related to the article,which would require application of the class objectives. This experience demonstrated that the active methodology can work as a facilitator for a contextualized and integrated approach to Biochemistry, reflecting in greater engagement and student performance, in addition to contributing to meaningful learning (AU).

An outreach activity to enhance biochemistry pedagogy.

Students are self-motivated to learn when provided opportunities that connect theory and real-world applications. Here, we describe for biochemistry majors a newborn screening-focused outreach activity that seeks to develop students' mastery of disciplinary content and soft skills (e.g., critical thinking, teamwork, effective communication, community engagement) and to enhance student engagement.

[Practices of integrating the undergraduate and graduate teaching of Biochemistry and Molecular Biology].

Biochemistry and Molecular Biology are the cornerstone courses of talent training in the field of life science. Taking these course as an example, this study explored reconstructing the knowledge framework, developing teaching cases, sharing teaching resources, innovating teaching means and establishing ideological education patterns. Supported by the scientific research achievements with discipline characteristics and online teaching platform, this research explored and practiced an integrated curriculum reform mode. This mode is guided by scientific research and education, based on the course development, and driven by communication and cooperation. A shared space of "exchange, practice, openness and informatization" was developed to achieve free and independent integration of undergraduate and graduate teaching motivated by learning knowledge, resulting in an effective student training.

Use of short videos and case studies to enhance student confidence in biochemistry knowledge and application in a large lecture biochemistry course in first year veterinary curriculum.

Large lecture courses are an efficient way to convey material to many students but have potential limitations, most notably the tendency for them to promote passive learning opportunities rather than active pedagogies. The curriculum at Cummings School of Veterinary Medicine at Tufts University, like many veterinary schools, contains many large lecture courses in the pre-clinical curriculum. This objective of this study was to use two active pedagogical interventions in a first-year lecture course named Veterinary Biochemistry and Metabolism that drew connections between basic science and several veterinary diseases. The first intervention targeted increasing students' intrinsic motivation and their confidence with understanding biochemistry concepts using videos created via collaborations between students, staff, and clinical and basic science faculty. The second intervention targeted active and collaborative learning via the implementation of clinical case studies completed in groups to relate lecture content to clinical scenarios with the aim of further enhancing student confidence in their knowledge of the material. To assess the effectiveness of these two interventions, pre-and post-course surveys using Likert style questions were administered to evaluate student confidence in the targeted concepts. The post-survey included open-ended responses on students' perspectives on their most important takeaways from the activities and their suggestions for improvements. The data showed a positive impact of these interventions on student motivation and confidence in their knowledge. This study provides support that targeted interventions to increase active learning strategies increase student engagement and may improve learning efficacy in large lecture courses.