Flexner 2.0—Longitudinal Study of Student Participation in a Campus-Wide General Pathology Course for Graduate Students at The University of Arizona

Introduction

At The University of Arizona, “Flexner 2.0” medical science courses are defined as medical sciences courses (eg, pathobiology, pathology, pharmacology, clinical microbiology) that are adapted from medical school curriculum and taught elsewhere in the university curriculum, ranging from college students to Doctor of Philosophy (PhD) students in biomedical engineering and Master of Public Health (MPH) students in public health. Flexner 3.0 was defined previously as medical science courses taught in K-12 schools. ¹ Medical schools teach “Flexner 1.0” courses. Flexner X.0 is a family of medical science courses that can be taught either in middle schools, high schools, colleges, or graduate schools.

In 1910, the Carnegie Foundation for Education in America published a seminal report, authored by Abraham Flexner (often referred to as the “1910 Flexner Report”), on medical education. This is credited with transforming the United States’ apprenticeship-based medical education industry into our current university-based medical education system by 1930. ^{2 –5} Flexner recommended that medical science coursework be designated “upper-level” university coursework. For all practical purposes, pathology coursework was reserved exclusively for medical students for the next hundred years. ^{2 –4,6} A century later, in anticipation of the 2010 Flexner Centennial celebrations, there was a crescendo of both interest and concern over what became known as the “collateral damages” of the 1910 Flexner Report. ^{7 –10} Calls for a reevaluation of US medical education, in general, and the restructuring of the entrance requirements for medical schools, in particular, grew louder. ^{7 –19} On the other hand, an unanticipated benefit of this reevaluation activity was the freeing up of traditional medical school pathology coursework for teaching in environments other than medical schools. Today, this is manifested by the migration of medical school coursework onto undergraduate college campuses and even into K-12 schools. Recently, we described the successful implementation of K-12 General Pathology in Arizona public district and public charter middle and high schools. ¹

The University of Arizona’s innovative K-12 General Pathology course was derived from the same medical college General Pathology Course used to create our graduate school “Mechanisms of Human Disease” (PATH 515) course described in this article. The PATH 515 content is more expansive than the K-12 General Pathology course to take advantage of the larger numbers of contact hours allocated to this graduate-level course. Other significant differences were the inclusion of 10 systems pathology lectures and 12 two-hour pathology laboratories in the graduate student version of the course (Appendix A, Appendix B, and Appendix C)

In this article, we provide longitudinal data on this single-semester graduate student course (PATH 515) based on course enrollment and student performance data sets collected over 19 consecutive years. We describe enrollment data and compare the performance of Master of Science (MS) degree students with PhD degree students.

Materials and Methods

Laboratories

A weekly, 2-hour laboratory session reinforced the lecture content by giving the students the opportunity to study gross and microscopic specimens of normal and relevant diseased organs and tissues. Normal anatomy and histology were reviewed in the first laboratory session and prior to the presentation of diseased tissues, as instruction for students lacking a strong background in these subjects. Between 1996 and 2008, students studied tissue histopathology sections and cytopathology specimens through light microscopes. Each student was given a slide set of 95 specimens; 23 represented normal histology and the remainder illustrated the disease processes covered in the course. Starting in 2009, digital microscopic images (whole slide images) were introduced (Figure 1). ²¹

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Figure 1.

Whole slide images. A, Acute myocardial infarct (upper left) with coagulation necrosis of myocytes and degenerating polymorphonuclear leukocytes. Hematoxylin and Eosin (H&E) staining; 20× final magnification. B, Invasive ductal carcinoma of the breast showing a mitotic figure (arrow). H&E staining; 100× final magnification. C, Gaucher cells (arrow) in the liver with the appearance in the cytoplasm of crumpled tissue paper. H&E staining; 100× final magnification. D, Plaque with dystrophic neurons surrounding an amyloid core in Alzheimer disease. Silver (Sevier-Munger) stain; 100× final magnification.

In each whole slide imaging laboratory, 10 tables accommodating 6 students each were arranged around a central instructor’s station, when the laboratory was used for medical students. A large format screen for viewing images was mounted on the wall adjacent to each student table. During the laboratory session, a faculty instructor “drove” the virtual microscope image to point out the key features of each tissue specimen for the laboratory. The virtual microscope control was then given over to the students in each group to allow for group study. The PATH 515 occupied 1 part of a medical student laboratory while the medical students were involved with other activities elsewhere. The medical students and the PATH 515 graduate students did not commingle in the laboratory.

Results

Programs of Study for Mechanisms of Human Disease Students

Table 1 lists the 21 programs of graduate school study (plus nondegree seeking students) for the 270 students who enrolled in and completed PATH 515 between 1997 and 2016.

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Table 1.

Graduate Programs of Students Enrolled in General Pathology (PATH 515).

	Number of Students by Degree Level
Program of Study	BS	Certificate	MS	PhD	Total
Cellular and Molecular Medicine	–	–	43	13	56
Applied Biosciences	–	–	39	–	39
Biomedical Engineering	–	–	6	25	31
Pharmacology and Toxicology	–	–	2	24	26
Cancer Biology	–	–	–	19	19
Physiological Sciences	–	–	4	8	12
Public Health		–	4	5	9
Nutritional Sciences	–	–	4	4	8
Microbiology and Immunology	–	1	2	4	7
Biomedical Sciences	–	6	–	–	6
Molecular and Cellular Biology	2	–	2	2	6
Veterinary Science and Microbiology	–	–	3	2	5
Miscellaneous*	1	–	4	8	13
Nondegree seeking					33
Total	3	7	113	114	270†

Abbreviations: BS, Bachelor of Science; MS, Master of Science; PATH 515, Mechanisms of Human Disease; PhD, Doctor of Philosophy.

*Agricultural and Biosystems Engineering (1 PhD); Anthropology (1 MS); Applied Mathematics (1 PhD); Biochemistry (1 BS, 1 MS); Genetics (2 MS, 1PhD); Medical Pharmacology (3 PhD); Optical Sciences (1 PhD); Pharmaceutical Sciences (1 PhD). Numbers in parenthesis indicate numbers of students in individual graduate programs.

^†Two hundred sixty-eight of 270 students received passing grades (≥70%) for the course.

Enrollment in the Course

For the first 7 years, 5 to 15 MS or PhD students enrolled in PATH 515 per year, with an average enrollment of 11 students per year. A large spike in enrollment, going from 14 students to up to 35 students per year took place between 2012 and 2014 (Figure 2). Postspike enrollment levels of approximately 30 student per year continue to the present time.

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Figure 2.

Class size for Mechanisms of Human Disease (PATH 515) from 1997 through 2016. The spike in enrollment (arrow) was caused by the introduction of new Master of Science (MS) degree programs emphasizing medical science.

Figure 3 shows the increased percentage of MS students enrolled in PATH 515 after 2012, following the designation of PATH 515 as a recommended course for MS degree programs in Cellular and Molecular Medicine, and in Applied Biosciences. Currently, well over half of the enrollees are in MS degree programs.

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Figure 3.

Changing pattern of degree type pursued by Mechanisms of Human Disease (PATH 515) students. Charts indicate the relative fractions of degree types being pursued by students enrolled in PATH 515 in the years from 1997 to 2012 and 2013 to 2016.

Student Evaluations of Mechanisms of Human Disease (1997-2016)

The percentage of students completing the evaluation survey per year is shown in Table 2. Overall, 160 responded. In 2015, we tried using an online system, with the students being asked to complete it on their own time. Given the low percentage of returns that year, we went back to the paper format.

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Table 2.

Percent Students (Number in Parentheses) Responding to Survey Each Year.

Year	% Survey Respondents
2007	73 (11)
2008	80 (8)
2009	92 (11)
2010	100 (8)
2011	92 (12)
2012	86 (12)
2013	92 (25)
2014	86 (30)
2015	50 (12)*
2016	97 (31)

* In 2015, we tried using an online system, with the students being asked to complete it on their own time. Given the low percentage of returns that year, we went back to the paper format.

Responses to questions on the student’s course evaluations were not significantly different from year-to-year (Table 3), despite changes in the composition of the classes and changes in the faculty over time. χ² results for course survey questions showed no significant differences as a function of year for any of the questions (Table 3). Course ratings and the ratings for individual components of the course (ie, outside help, course textbook, etc) received nearly all “outstanding” or “satisfactory” ratings. A “poor” rating was given only 5 times over the 19-year period (2 times for the textbook, 1 time for “outside help,” 1 time for the Web site, and 1 time for laboratory presentations). Over the 19-year period, there were no differences in trends for the way individuals responded to the survey questions. Results from student course evaluations demonstrated a high level of student satisfaction with the course.

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Table 3.

Student Evaluations of PATH 515.

Question	Mean (SD)	Median (IQR)	X2	P Value
Overall quality of the course	1.24 (0.43)*	1.0 (0.0)	0.567	.9038
Contribution to my education	1.24 (0.43)	1.0 (0.0)	1.290	.7315
Outside help (2014 and 2013 only)	1.40 (0.53)	1.0 (1.0)	5.397	.2489
Course Web site	1.52 (0.55)	1.0 (1.0)	1.982	.7391
Course textbook	1.62 (0.54)	2.0 (1.0)	2.275	.8927
Laboratory organization	1.41 (0.49)	1.0 (1.0)	4.831	.1846
Laboratory content	1.41 (0.51)	1.0 (1.0)	3.819	.7012
Laboratory handouts	1.33 (0.47)	1.0 (1.0)	4.035	.2577

Abbreviation: PATH 515, Mechanisms of Human Disease.

* Rating scale: 1 = excellent; 2 = good; 3 = poor; and 4 = unsatisfactory.

The comments (n = 172) from the students were analyzed to categorize them into themes. An initial review revealed 4 themes—(1) the variety and breadth of topics covered, (2) connecting what happens at a gross level in the tissue to underlying cellular processes, (3) the format of providing general pathology concepts followed by lectures on specific pathology taught by experts, and (4) a hands-on experience in the laboratory to reinforce the content taught in the lecture. Two authors (M.M.B. and M.A.N.) then independently reviewed each comment and placed it in one of the categories, using category 5 if it did not fit in any of the 4. Discrepancies in scores (131 of 172) were resolved by a third independent reviewer (E.A.K.). Overall, 67 (39%) were classified as category 1, 26 (15%) as category 2, 27 (16%) as category 3, 29 (17%) as category 4, and 23 (13%) as category 5.

Some typical examples of comments from each category are:

Category 1: “The variety of material covered and that the class is useful to a variety of majors rather than aimed at a particular set of programs.” “Breath (sic) of information was great.”

Category 2: “Seeing gross specimens and then observing what happens on a cellular level.” “Gross specimens and microscopic images in laboratory.”

Category 3: “Multiple different professors give richer material.” “Each discipline was taught by someone who specialized in the area.”

Category 4: “I liked the ‘hands-on’ training in the laboratory and being able to explore the micrographs on a digital eyepiece.” “The ‘hands on’ aspect of this course is absolutely amazing and a very valuable asset. I truly believe more graduate programs should require students to take this course.”

Category 5: “Easy learning environment, good presentations.” “The information was very interesting.”

Discussion

The PATH 515 represents an addition to the growing list of “Pathology for Non-Pathologists” courses offered in the United States. Such courses circumvent the Flexnerian “virtual monopoly” of pathology courses by medical schools. Our 20-year experience with the PATH 515 course has proven its popularity and utility for postbaccalaureate students who are pursuing biomedical science careers that require advanced degrees other than an MD.

Arguably, the first Pathology for Non-Pathologists course was pioneered a half century ago at Harvard Medical School (HMS), in the mid-1960s. Two distinguished HMS Pathology professors, Ramzi Cotran, MD, and Morris Karnovsky, MBBS, applied for and received a grant from the Commonwealth Fund to create a Boston city-wide course for graduate school students called Pathology for Non-Pathologists. Graduate students from more than 6 local universities enrolled. These annual courses accommodated 100 to 150 students each year and were given on the HMS campus. The primary focus was on mechanisms of diseases. The course mirrored the General Pathology course being taught to medical students at HMS in the late 1960s. This year-long course met once a week from 4:30 to 6:00 pm. Some lectures had a greater research focus than the HMS student lectures on the same topic (Weinstein, 1968, unpublished observations). In 1966, an author of this article (R.S.W.) had recently been promoted to a dual role as a pathology resident at the Massachusetts General Hospital (MGH) and director of the NIH-funded Mixter Laboratory for Electron Microscopy of the MGH Neurosurgical Service. Dr Cotran, a mentor of Dr Weinstein, invited him to audit the Pathology for Non-Pathologists Course and provide the course directors with a critique of the course. This led to career-long collaborations between Drs Cotran and Weinstein on developing innovative pathology courses for medical students, residents, and faculty members.

In the late 1970s and early 1980s, Dr Cotran and Dr Weinstein were co-course directors for a “spin-off” series of half-day Pathology for Non-Pathologist short courses, given annually at meetings of the United States and Canadian Academy of Pathology (USCAP). Their target audiences for these courses were Pathology Department PhDs and Doctors of Veterinary Medicine (DVMs) who served as faculty members for their institution’s general pathology courses. Many of the USCAP short course presentations were then expanded on, and published in, an annual series entitled “Advances in Pathology and Laboratory Medicine.” ²² Today, a Google search shows that the course descriptor Pathology for Non-Pathologists is in common usage elsewhere. ²³

This article documents The University of Arizona’s Department of Pathology’s experience teaching Pathology for Non-Pathologists coursework to 270 graduate students based on a wide variety of MS and PhD graduate programs at The University of Arizona, over a 19-year period. The data for the first year of the 20-year program, to date, was incomplete and is not included. Three levels of postbaccalaureate programs are available at the University of Arizona—certificate, MS, and PhD. All 3 were represented in enrollment for PATH 515. The course has also attracted a number of nondegree seeking, postbaccalaureate students. Programs that have brought in the greatest numbers of MS degree students to the PATH 515 course are Cellular and Molecular Medicine and Applied Biosciences (Table 1). The former degree is used as foundation for additional graduate studies (eg, MD or PhD) or for positions in basic and translational clinical research. Applied Biosciences is a 2-year course of study designed to prepare students to competitively enter the scientific workforce, applying the biological sciences to solve problems faced by public institutions and private industry. In the group of students pursuing PhD, the PATH 515 course attracts the largest numbers of students from programs in Biomedical Engineering, Pharmacology and Toxicology, Cancer Biology, and Physiological Sciences.

The PATH 515 faculty members found that weekly, 2-hour, pathology laboratories could be taught to a diverse student body, including students coming into the course with little knowledge of biology, chemistry, and histology. We avoided creating any course prerequisites. The assumption was that the standard “premedical science courses, including biology, inorganic and organic chemistry, and physics, were nonessential for the subsequent mastery of medical science courses in graduate school, an increasingly popular notion in many circles today. ^{14,17 –19} Incorporating the minimum of premedical science into the PATH 515 course enabled students from very diverse disciplines to achieve high scores on the PATH 515 quizzes and examinations. As an example, we reviewed the gross morphology of the heart in relation to the pulmonary and systemic circulations. Therefore, the absence of traditionally required preparatory coursework was not an impediment to performing well in the course.

Some revisions to the PATH 515 course were made over the years in response to advances in medical science, in education technologies, and to changes in department faculty composition. As an example of advances in medical sciences, a lecture on genetics was revised to cover present methodologies in molecular medicine and discoveries made as the result of subtyping lymphomas based on gene signatures. Major changes in response to advances in teaching technologies were the replacement of light microscope histopathology slides with whole slide images and gross pathology specimens with 3-dimesional photography images. In 2009, the University of Arizona’s College of Medicine implemented whole slide images for teaching pathology to medical students. The PATH 515 course is taught in College of Medicine classrooms and began using digital pathology technology shortly after it was implemented for medical students. In their PATH 515 course evaluations, the graduate students commented favorably on the effectiveness and convenience of using whole slide images. The students noted that having access to the images outside of the laboratory, through Web-based programs, was particularly useful.

In their course surveys, students were asked to comment, in the free-text portion, on what they “liked best about the course.” Common themes were—(1) the variety and breath of topics covered; (2) connecting what happens, at a gross level in the tissue, to underlying cellular processes; (3) the format of providing general pathology concepts followed by lectures on systems pathology taught by experts; and (4) a hands-on experience in the laboratory to reinforce the content taught in the course. In response to the question of what they “liked least,” a handful of students noted that having a panel of 5 to 7 teachers was a drawback. In response to this comment, we reduced the total number of instructors in the course. This was achieved by having the general pathology part of the course taught entirely by just 2 faculty with new faculty coming in assigned to systems pathology lectures. Furthermore, when faculty who had taught system pathology lectures moved away, these lectures were reassigned to the 2 faculty members who gave the general pathology lectures. Our goal was to have the number of faculty reduced to just 3 or 4. For this introductory course, our surgical pathologists and autopsy pathologists were prepared to give lectures on several organ systems each.

As an interesting twist of fate, the 1910 Flexner Report’s recommendations that pathology be upper level university coursework ² inadvertently reserved the teaching of much of pathology exclusively for medical students. This resulted in a large segment of the population having no exposure to pathology education. The pervasive lack of exposure to pathology education among nonmedical students provides an excellent opportunity to observe what, if any, course prerequisites significantly impact a person’s ability to learn pathology.

It is noteworthy that the 1910 Flexner Report was published at a time when medical doctors represented nearly half of the health-care workforce. The other half consisted mainly of licensed practical nurses. Registered nursing programs were barely on the radar screen. ^24,25 Flexner’s recommending that medical science be upper level coursework at US universities reflected what had been established at the German university-based medical schools as their preferred way of educating future medical doctors. This became the aspirational model for United States’ medical schools following the publication of the Carnegie Foundation’s Flexner Report in 1910. The German university model had been successfully implemented at only a handful of US medical schools before that time, a century ago. ^{2 –5}

Flexner 2.0 is relevant to current workforce issues. Today, the makeup of the health-care workforce is very different than it was a century ago. The needle has barely moved with respect to numbers of physicians per 100 000 population in the United States, since 1850, according to DC Baldwin, MD, a Scholar-in-Residence at the Accreditation Council for Graduate Medical Education. (DC Baldwin, personal communication, 2013). ^24,25 The 20-fold expansion of the US health-care workforce over the past century has gradually reduced physicians’ representation in the workforce to less than 8% of the total workforce today. ²⁴ This translates into an ever-increasing proportion of the health-care workforce lacking exposure to pathology coursework on mechanisms of diseases. This may directly impact on the scope of team training in clinical practice. Conversely, by broadening the base of students who have prior knowledge of mechanisms of diseases, the range of topics suitable for interdisciplinary team training is expanded as well. ^{1,26 –28}

Today, the 1910 Flexner Report recommendations can be linked to the underrepresentation of pathology coursework on mechanisms of diseases in nursing schools and pharmacy schools as well as many other categories of health education programs such as the allied health sciences. In addition, the restriction of pathology coursework to medical schools has severely limited the potential exposure of college students, as well as K-12 students, to what academic pathologists still define as “general pathology.” ¹ The impact of the maldistribution of pathology coursework throughout the US education system on the low level of health literacy in the general population in the United States is a matter for future investigation. ^29,30

On the other hand, what is now becoming apparent is that the century-long exclusion of pathology as coursework for the vast majority of US students, at all levels in the education system, inadvertently created a level playing field for the introduction of pathology to large segments of the population today, a previously unanticipated opportunity from the perspective of health education research. Now, having been partially freed of the Flexnerian premedical science coursework requirements, biology, inorganic and organic chemistry, and physics, which were in place for a century but are now beginning to fade in popularity, greater flexibility exists for curriculum planners with regard to identifying and justifying their preferred grade levels for the inclusion of pathology courses in a broad spectrum of science curriculums. ¹⁹ As reported previously, we showed that pathology coursework can be adapted for use by motivated students in public district and public charter K-12 schools. ¹

In this study, we have now tested the feasibility of introducing pathology coursework at the upper end of the education spectrum, by teaching such coursework to MS and PhD students drawn from 21 different graduate programs, in the physical and biological sciences at a research university. Having shown that medical science can be taught at multiple levels throughout the education system, without prior student exposure to the traditional premedical sciences, serious thought should be given to preferentially introducing such pathology coursework at grade levels on which it would have the greatest positive impact on the health and welfare of the general population. Our finding that PATH 515 was especially attractive to MS students is noteworthy given that MS degree programs are rapidly proliferating on university campuses today. Academic pathologists interested in public policy should be encouraged to become involved in creating an inclusive national vision for medical science education for nonphysicians in order to increase public awareness concerning the broadening of opportunities in the health-care industry and the benefits of personal knowledge about the nature of diseases as active participants in their own health care.