ERIC Number: EJ1394318
Record Type: Journal
Publication Date: 2023-Jun
Pages: 14
Abstractor: As Provided
ISBN: N/A
ISSN: ISSN-1043-4046
EISSN: EISSN-1522-1229
Oaks to Arteries: The Physiology Core Concept of Flow down Gradients Supports Transfer of Student Reasoning
Doherty, Jennifer H.; Cerchiara, Jack A.; Scott, Emily E.; Jescovitch, Lauren N.; McFarland, Jenny L.; Haudek, Kevin C.; Wenderoth, Mary Pat
Advances in Physiology Education, v47 n2 p282-295 Jun 2023
The Physiology Core Concept of flow down gradients is a major concept in physiology, as pressure gradients are the key driving force for the bulk flow of fluids in biology. However, students struggle to understand that this principle is foundational to the mechanisms governing bulk flow across diverse physiological systems (e.g., blood flow, phloem sap flow). Our objective was to investigate whether bulk flow items that differ in scenario context (i.e., taxa, amount of scientific terminology, living or nonliving system) or in which aspect of the pressure gradient is kept constant (i.e., starting pressure or pressure gradient) influence undergraduate students' reasoning. Item scenario context did not impact the type of reasoning students used. However, students were more likely to use the Physiology Core Concept of "flow down [pressure] gradients" when the pressure gradient was kept constant and less likely to use this concept when the starting pressure was kept constant. We also investigated whether item scenario context or which aspect of the pressure gradient is kept constant impacted how consistent students were in the type of reasoning they used across two bulk flow items on the same homework. Most students were consistent across item scenario contexts (76%) and aspects of the pressure gradient kept constant (70%). Students who reasoned using "flow down gradients" on the first item were the most consistent (86, 89%), whereas students using "pressures indicate (but don't cause) flow" were the least consistent (43, 34%). Students who are less consistent know that pressure is somehow involved or indicates fluid flow but do not have a firm grasp of the concept of a pressure gradient as the driving force for fluid flow. These findings are the first empirical evidence to support the claim that using Physiology Core Concept reasoning supports transfer of knowledge across different physiological systems.
Descriptors: Physiology, Science Instruction, Teaching Methods, Concept Formation, Scientific Concepts, Undergraduate Students, Biology, Abstract Reasoning, Homework, Transfer of Training, Vignettes, Introductory Courses, Plants (Botany), Animals
American Physiological Society. 9650 Rockville Pike, Bethesda, MD 20814-3991. Tel: 301-634-7164; Fax: 301-634-7241; e-mail: webmaster@the-aps.org; Web site: https://bibliotheek.ehb.be:2487/journal/advances
Publication Type: Journal Articles; Reports - Research
Education Level: Higher Education; Postsecondary Education
Audience: N/A
Language: English
Sponsor: National Science Foundation (NSF), Division of Undergraduate Education (DUE)
Authoring Institution: N/A
Grant or Contract Numbers: 1661263; 1660643