Ginevra A. Clark scite author profile

An understanding of protein folding relies on a solid foundation of a number of critical chemical concepts, such as molecular structure, intra-/intermolecular interactions, and relating structure to function. Recent reports show that students struggle on all levels to achieve these understandings and use them in meaningful ways. Further, several reports show that the visualization techniques employed to help students understand protein structure often lead to confusion and propagate further misconceptions. Here, we report on a lab exercise using computer-based modeling to support student proficiency in using and making models and understanding H-bonding and the hydrophobic effect in the context of protein folding. We analyzed student drawings and explanations of protein structure and found significant improvements from pre- to postlab, indicating that students improved their understanding of protein folding. Further, we report on how we systematically refined our laboratory materials based on student work.

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Dialysis, Albumin Binding, and Competitive Binding: A Laboratory Lesson Relating Three Chemical Concepts to Healthcare

Domingo

Abualia

Barragan

et al. 2017

J. Chem. Educ.

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Introductory Chemistry laboratories must go beyond "cookbook" methods to illustrate how chemistry concepts apply to complex, real-world problems. In our case, we are preparing students to use their chemistry knowledge in the healthcare profession. The experiment described here explicitly models three important chemical concepts: dialysis of small molecules (dye), reversible binding (dye binding to albumin), and competitive binding (dye and a competitor binding to albumin). Moreover, each concept is intimately related to a physiological phenomenon: dialysis is used to treat renal failure, drugs travel in the blood bound to albumin, and competitive albumin binding is a common drug− drug interaction. In the context of this simple series of experiments, students create models, use evidence to validate their models, and finally use their understanding to describe physiological phenomena. This laboratory experiment was implemented in a 100level course for predominantly prenursing majors. Student pre-and postlab models were examined, illustrating an improved conceptual understanding upon performing the lab and use of evidence to improve or support models. This experiment can be performed in 1 h, and can be adapted as a lecture demonstration.

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Urinalysis and Prenatal Health: Evaluation of a Simple Experiment That Connects Organic Functional Groups to Health Equity

et al. 2019

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Knowledge of functional groups provides students with a language for organic chemistry. However, students in a health science chemistry course do not plan to be synthetic organic chemists and, therefore, need examples of how functional group chemistry is relevant to their vocational goals. We have developed a lab to demonstrate how simple functional group chemistry is used in laboratory testing, namely, the "pee test", or dipstick urinalysis. Dipstick urinalysis is frequently used to screen for various conditions and is used weekly in the last month of pregnancy. Our lab models the prenatal clinical environment. The laboratory allows for testing of chemical species that support a medical diagnosis: albumin testing for preeclampsia; leukocytes, nitrites, and pH for urinary tract infection; glucose, ketones, and pH to test for gestational diabetes, alcoholism, or other serious metabolic diseases. The related lessons are designed to support students in understanding the reactions involved in testing, biochemistry related to diagnosis, and general understandings of how tests are interpreted. In developing this experiment, we were confronted with disparities in prenatal care, namely, the absence of culturally competent care, inequitable access to care, and toxic stress due to racism that contribute to dramatically increased maternal death rates for women of color in the US. We identified resources to educate students on culturally competent care. These resources include reference to the way in which the "pee test" is administered. We have incorporated this resource into our lab with appropriate reflection questions, based on our newly devised cultural competence and social justice framework for chemistry students. Our findings indicated that student understandings of the chemistry and testing methods were adequate; on average, 77% of samples were properly diagnosed. With respect to social justice and cultural competence, we found that students predominantly discussed two elements of the cultural competence and social justice framework: reflection on privilege in society and agency to promote equity in healthcare.

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Relating Chemistry to Healthcare and MORE: Implementation of MORE in a Survey Organic and Biochemistry Course for Prehealth Students

et al. 2017

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We implemented a laboratory curriculum reform to teach foundational concepts in chemistry, particularly those concepts related to healthcare, in a chemistry course for prenursing students. Here, we discuss the reform, exploring how students built upon understandings gained in lab and correlating lab learning to course outcomes. We further discuss shifts in student work as they move through the course. As the course progressed, students became familiar with the pedagogy but also faced more challenging tasks. We present details on several of the laboratories that build the groundwork for understanding chemical principles, including the following: intermolecular forces, physical properties, acid–base chemistry, equilibrium, and chemical reactions. We further share our observations of student interactions around in-lab prompts and activities, and how these interactions inform our teaching. Our reform aims to improve critical thinking skills, namely, making and using models, observation skills, reasoning with evidence, and applying concepts to new problems. The laboratory procedures presented here modify those commonly found in the chemistry curriculum with a consistent student-centered pedagogy. We hope the simplicity and popularity of the lab procedures will allow for broad implementation of Rickey’s MORE (Model, Observe, Reflect, Explain) pedagogy, and we hope our lessons in implementation will broadly benefit those who are implementing new lab curricula.

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Ginevra A. Clark

Biosynthesis and Stability of Coiled‐Coil Peptides Containing (2S,4R)‐5,5,5‐Trifluoroleucine and (2S,4S)‐5,5,5‐Trifluoroleucine

Connecting Protein Structure to Intermolecular Interactions: A Computer Modeling Laboratory

Dialysis, Albumin Binding, and Competitive Binding: A Laboratory Lesson Relating Three Chemical Concepts to Healthcare

Urinalysis and Prenatal Health: Evaluation of a Simple Experiment That Connects Organic Functional Groups to Health Equity

Relating Chemistry to Healthcare and MORE: Implementation of MORE in a Survey Organic and Biochemistry Course for Prehealth Students

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