Characteristics of Physiology and Physiology-Related Pre-Health Degree Programs in the Physiology Majors Interest Group

The Physiology Majors Interest Group (P-MIG), a grassroots organization of educators, has collected data on the history and characteristics of Physiology and highly related undergraduate programs (ex: Human Biology, Pre-Medicine, Biomedical Sciences, etc.) that serve a common population of prehealth students. Data was obtained as part of an online survey sent out to P-MIG conference attendees at the 2017-2019 annual meetings (n=30). Participating institutions indicate that 25.9% have degrees called Physiology aligned with 28% being housed in a department of physiology, 75.9% are a Bachelor of Science program, 34.9% are affiliated with a College of Arts and Sciences, and 80% have a human/integrative physiology emphasis. Further, 47.6% of programs are greater than 10 years old and 100% have seen either no change or an increase in enrollment over the past 5 years. Most programs have a dedicated advising staff (68.2%) and formalized learning objectives for the major (61.9%). 34.1% have a curriculum committee who oversees the major. Program sizes vary widely from less than 50 to over 2000 students. While there is diversity in departmental organization and management structure in the programs, a commonality is that all programs are preparing students with aspirations in careers in healthcare. We report the similarities and differences between these programs to allow for advisors to better understand the broad landscape of pre-health programs at the undergraduate level

The Case for Coordinating Efforts to Establish Program Guidelines and Strengthen Physiology Undergraduate Degree Programs

Undergraduate degree programs named “Physiology” have existed for over 50 yr. The number of programs and enrolled students have been growing since ~2005 (5, 9). There are many thousands of students currently enrolled in physiology pro- grams across the United States and indeed across the world. Despite the long history and current popularity of the physiol- ogy major, there is no coordinated plan articulated for the design, administration, or assessment of degree programs in physiology at the undergraduate level. Although several professional societies have invested in under- graduate physiology education in various ways, none has under- taken the task of developing programmatic guidelines at the level of a degree program. This paper outlines the work being done by multiple stakeholders in physiology undergraduate education in the hopes of building a collaboration among interested parties. A large-scale collaboration could result in establishing consensus national programmatic guidelines. Through coordinated efforts, we ensure that entities with common educational interests are working together, and we collectively strengthen our programs to help our students succeed. The goals of this paper are to: 1) draw attention to the lack of national, program-level guidelines for physiology under- graduate degree programs; 2) share ongoing efforts by stake- holders in physiology undergraduate education; 3) suggest a mechanism for coordination among stakeholders; and 4) dis- cuss challenges and considerations for development of pro- grammatic guidelines for physiology programs

Acetylcholine Protection of Adult Pig Retinal Ganglion Cells from Glutamate-Induced Excitotoxicity

PURPOSE. To determine which glutamate receptor (GluR) subtypes are responsible for glutamate-induced excitotoxicity in cultured adult pig retinal ganglion cells (RGCs) and to characterize the neuroprotective effect of acetylcholine (ACh) on pig RGCs. METHODS. Adult pig RGCs were isolated from other retinal tissue by a modified panning technique using Thy 1.1 antibody. Isolated RGCs were cultured in control media and media containing: glutamate, NMDA, or KA; glutamate and CNQX, MK-801, or AP-7; ACh, nicotine or muscarine; ACh and α-bungarotoxin (Bgt) or methyllycaconitine (MLA); and glutamate and choline or glutamate, choline, and MLA. To determine cell viability, cells were loaded with calcein and counted. RESULTS. Ninety-eight percent of isolated cells were immunolabeled with Thy 1.1 antibody. Chronic exposure to 500 μM glutamate decreased the number of surviving large and small RGCs, compared to control conditions. This glutamate-induced excitotoxicity was mediated through both NMDA and non-NMDA GluRs. In neuroprotective studies, ACh, nicotine, and choline significantly reduced glutamate-induced excitotoxicity in adult pig RGCs through α-Bgt-sensitive nicotinic ACh receptors (nAChRs). DISCUSSION. This was the first report of a modified panning technique to isolate adult pig RGCs. Cell viability was relatively high using this method, and both large and small RGCs grew extensive neurites in culture. The finding that both NMDA and non-NMDA GluRs were involved in glutamate-induced excitotoxicity suggests that isolated pig RGCs provide a good model for glaucoma. In addition, activation of AChRs may be useful in protecting RGC from excitotoxic insults occurring in neurodegenerative diseases such as glaucoma