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CC BY-NC-ND 4.0 · Journal of Academic Ophthalmology 2017; 09(01): e13-e20
DOI: 10.1055/s-0037-1604364
Research Article
Thieme Medical Publishers 333 Seventh Avenue, New York, NY 10001, USA.

A Clinical Vision Research Training and Mentoring Program as a Model for Ophthalmology and Other Medical Specialties: Implementation and Evaluation

Lisa Hark
1   Glaucoma Research Center, Wills Eye Hospital, Philadelphia, Pennsylvania
2   Department of Ophthalmology, Sidney Kimmel Medical College, Philadelphia, Pennsylvania
,
Julia A. Haller
2   Department of Ophthalmology, Sidney Kimmel Medical College, Philadelphia, Pennsylvania
3   Ophthalmologist-in-Chief office, Wills Eye Hospital, Philadelphia, Pennsylvania
,
Ann P. Murchison
2   Department of Ophthalmology, Sidney Kimmel Medical College, Philadelphia, Pennsylvania
4   Department of Research, Wills Eye Hospital, Philadelphia, Pennsylvania
,
Michael Waisbourd
5   Division of Ophthalmology, Tel Aviv Medical Center, Sackler Faculty of Medicine, Tel Aviv University, Tel Aviv, Israel
,
Eileen L. Mayro
4   Department of Research, Wills Eye Hospital, Philadelphia, Pennsylvania
,
David M. Weiss
6   Department of Psychology, Ohio State University, Columbus, Ohio
,
Safa Siraj
1   Glaucoma Research Center, Wills Eye Hospital, Philadelphia, Pennsylvania
,
Carrie Wright
7   Ophthalmology Residency Program, Penn State Milton S. Hershey Medical Center, Hershey, Pennsylvania
,
Kathryn Scully
8   Department of Nursing, Hahnemann University Hospital, Philadelphia, Pennsylvania
,
Edward Jaeger
9   Department of Medical Education, Wills Eye Hospital, Philadelphia, Pennsylvania
› Author Affiliations
Further Information

Address for correspondence

Lisa Hark, PhD, RD
Department of Research, Wills Eye Hospital
840 Walnut Street, Suite 802, Philadelphia
PA 19107   

Publication History

26 October 2015

21 June 2017

Publication Date:
25 July 2017 (online)

 
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Abstract

Background Over the past 50 years, there has been a decline in the number of physicians pursuing careers in clinical research. In ophthalmology, the need for clinician-investigators continues to grow with the increasing eye-care demands of the aging population. Expert panels have recommended exposing medical students early in their training to structured, didactic curricula with clinical research experience and mentoring opportunities.

Methods To address this need, the Department of Research, Wills Eye Hospital, developed an 8-week Clinical Vision Research Training and Mentoring Program for undergraduate and medical students. The curriculum included an 11-hour lecture series on topics in research methods in ophthalmology and a 10-hour scientific writing workshop series. The program also involved hands-on participation in vision research projects and shadowing in one of Wills' subspecialty services. Students completed 40-question pre- and posttests on ophthalmology and research methodology. Scores were analyzed using a paired-sample t-test. The program also utilized a satisfaction survey.

Results During 2014 and 2015, a total of 34 students out of 56 applicants were accepted to the Clinical Vision Research Training and Mentoring Program. Students scored significantly higher on the posttest (mean [M] = 79.78%, standard deviation [SD] = 6.25) than on the pretest (M = 71.43%, SD = 8.43); p< 0.001. Using a satisfaction survey, students strongly agreed that they were satisfied with the program and that the lecture series and manuscript writing workshops enhanced their learning.

Conclusions The Wills Eye Clinical Vision Research Training and Mentoring Program provided an evidence-based foundation in research methods and manuscript development for students interested in careers in ophthalmology. Students emerged with clinical research skills and an increased understanding and appreciation of vision research. Results of the pre- and posttest analysis indicate that lecture material supplemented with hands-on experience can lead to better understanding of ophthalmology. This pilot program can serve as a research training and mentoring model for ophthalmology and other medical and surgical specialties.


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Keywords

ophthalmology - mentoring - medical student - clinical research - clinician-investigator - training model - vision research

Over the past 50 years, the medical field has seen a marked decline in the number of physicians pursuing careers in clinical research.[1] James Wyngaarden, MD, former director of the National Institutes of Health (NIH), first noted this decrease in the late 1970s. He called clinical investigators an endangered species in an atmosphere focused on basic science over patient-oriented research.[2] Years later, Weinreb revisited this issue, underscoring the increasing difficulties that clinician-scientists face in getting funding while maintaining clinical productivity.[3] In recent decades, attempts to address this shortage have included formalizing research training during clinical years to ensure that it remains a career-long priority.[4]

Several expert committees—including the NIH Director's Panel on Clinical Research,[5] the Institute of Medicine's Clinical Research Roundtable,[6] and the Association of American Medical Colleges' second Clinical Research Task Force (CRTFII)[7]—have generated recommendations and funding mechanisms for implementing clinical research education in the United States. Specific points highlighted by these expert panels include the need for a structured, didactic curriculum that incorporates a core knowledge base; practical clinical research experience; mentorship opportunities; protected research time for mentors; and formal recognition, such as a certificate or master's degree. All of these panels emphasize the importance of introducing medical students and physicians to clinical research as early as possible in their training.[5] [6] [7]

The creation of the National Eye Institute (NEI) in 1968 was a seminal event for vision research. The NEI legitimized the field of ophthalmic research, its research budget growing from $24 million in 1970 to $500 million in 2000 and to $708 million in 2017.[8] Research projects supported by the NEI address the leading causes of blindness and impaired vision in the United States. The NEI currently funds multiple awards for mentored clinician-scientists, including the Mentored Clinical Scientist Research Career Development Award (K08), the Mentored Clinical Scientist Development Program Award (K12), the Mentored Patient-Oriented Research Career Development Award (K23), and the Pathway to Independence Award (K99/R00).[9]

The NEI K30 Clinical Research Curriculum Award is now a part of the NIH Clinical and Translational Science Awards (CTSA) program, which was started in 2006 to strengthen and support clinical and translational research (CTR). A national consortium of 62 academic health centers are supported to transform and accelerate CTR. Recognizing the urgent need to increase the pipeline of CTR investigators, the CTSA has emphasized Research Education and Career Development of junior CTR investigators.[10] [11]

While there are more than 450 ophthalmology residents in the United States graduating annually, only 39 K08 and 6 K12 awards were funded by the NEI in 2017.[12] In fact, the number of physician-scientists receiving postdoctoral research training and career development awards is at an all-time low.[13] In addition, only 2% of ophthalmologists are actively involved in research activities and this number will likely decline further in the foreseeable future.[14] Thus, physician-scientists are less likely to engage in biomedical research than in the past years. The number of physicians supported by NIH training and fellowship grants has also declined, even though the number of applications for funding has increased.[3] [13] The dearth of clinician-scientists in ophthalmology is particularly critical to address because of the increase in eye-care demands of the aging U.S. population.

Despite available NEI funding mechanisms, few ophthalmologists become clinician-scientists due to lack of time to write clinical research grants and limited research training during medical school, residency, and fellowship programs. However, ample evidence suggests that exposing students to clinical research during medical school helps increase their interest in research careers.[13] [15] Early commitment to the career path of clinician-scientist, especially prior to or during the resident training phase, is key to retaining the best ophthalmologists in academic careers. In addition, formal mentoring programs are effective in helping junior investigators become independent researchers.[16]

In an effort to provide a structured, didactic curriculum with practical, clinical research experience for students interested in ophthalmology early in their careers, we developed an 8-week Clinical Vision Research Training and Mentoring Program for undergraduate and medical students. Wills Eye Hospital, established in 1832 as the nation's first hospital specializing in eye care, is a global leader in ophthalmology. U.S. News & World Report currently ranks Wills Eye Hospital as one of the top two ophthalmology hospitals in the country. The clinical expertise, state-of-the-art diagnostic testing center, and advanced surgical capabilities make Wills a worldwide referral center, which annually treats more than 300,000 patients. Subspecialty services include glaucoma, neuroophthalmology, retina, ocular oncology, pediatrics and ocular genetics, ocular pathology, cornea, and oculoplastic and orbital surgery. Wills also serves as the Department of Ophthalmology for Sidney Kimmel Medical College at Thomas Jefferson University and their medical students rotate through Wills during required and elective ophthalmology courses as well as clinical clerkships. This article describes the program's aims, course content, lecture series, and evaluation data during the summer of 2014 and 2015.

Methods

Setting

Program Goals and Objectives

The program was developed, implemented, and evaluated by the Director of the Glaucoma Research Center at Wills Eye Hospital. Two cohorts of students took part in the Clinical Vision Research Training and Mentoring during the summers of 2014 and 2015. The full-time, 8-week program offered clinical research training, hands-on research experience, and mentorship to 34 students from 12 institutions in Pennsylvania, New York, New Jersey, Ohio, Georgia, and the District of Columbia ([Table 1]). With the largest clinical volume of patients with eye disease in the United States, Wills offers a unique opportunity for students to gain useful clinical research experience in ophthalmology.

Table 1

Students' university enrollment (n = 34)

Type of student

Quantity

University represented

Undergraduate (pre-medicine)

4

Columbia University

University of Pennsylvania

Emory University

LaSalle College

Undergraduate (public health)

1

Temple University

Graduate (medical school)

29

Sidney Kimmel Medical College at Thomas Jefferson University

Drexel University College of Medicine

Temple University School of Medicine

Philadelphia College of Osteopathic Medicine

Robert Wood Johnson School of Medicine

George Washington School of Medicine

Northeast Ohio Medical University

Source: Wills Eye Clinical Vision Research Training and Mentoring Program (used with permission, 2017).


The program goals and objectives were to engage students in the following:

  • Actively participate in a vision research project.

  • Conduct vision-related literature reviews.

  • Write a scientific article for a peer-reviewed journal.

  • Receive mentoring from faculty and research staff.

This program gave students a unique introduction to ophthalmology, experience in clinical research, and the skills necessary to conduct vision research. Students worked with a multidisciplinary group of research coordinators and managers, biostatisticians, data managers, and ophthalmologists to advance their knowledge, improve their manuscript writing skills, and engender positive attitudes about vision research. Mentorship was a key element of the program, with each student assigned to an investigator and a member of the research team.


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Recruitment and Admissions

The 2014 and 2015 Clinical Vision Research Training and Mentoring Program was directed by the Department of Research at Wills Eye Hospital. The program was posted on the Department of Research, Wills Eye Hospital, and Sidney Kimmel Medical College Web sites. Candidates submitted a curriculum vitae, a letter of recommendation, and a cover letter to the Department of Research Director in January 2014 and January 2015. The director, faculty members, research managers, and human resources director conducted personal interviews, selected students who had an interest in ophthalmology, prior research experience, and planned to apply to medical school if they were an undergraduate student. Seventeen undergraduate and medical students were selected and enrolled each year from a total of 25 applicants in 2014 and 31 applicants in 2015.


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Lecture Series

Many students entering the program had only a generalized knowledge of ocular disease and basic research methodology. To familiarize students with common ophthalmic conditions, as well as the basic principles of clinical research, an 11-hour lecture series was developed and presented by Wills Eye Hospital and Sidney Kimmel Medical College faculty. Lectures discussed glaucoma, optic neuropathy, and other ocular diseases; several ongoing research studies being conducted at Wills and the Institutional Review Board (IRB) policies ([Table 2]). Students participated in research projects related to these lectures.

Table 2

Lecture topics

Lecture

Topic

1

Introduction to ophthalmology

2

Introduction to glaucoma

3

Introduction to neuro-ophthalmology and optic neuropathy

4

Introduction to diabetes and diabetic retinopathy

5

Introduction to age-related macular degeneration

6

Introduction to cataract and refractive surgery

7

Introduction to smoking and eye disease

8

Glaucoma community outreach demonstration project

9

Quality-of-life study for glaucoma

10

Transcorneal electrical stimulation study for optic neuropathy

11

Institutional Review Board policies and procedures

Source: Wills Eye Clinical Vision Research Training and Mentoring Program (used with permission, 2017).



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Clinical Research Skills and Experience

The program provided students with a framework for research design, critical analysis, and the practical skills needed to pursue an academic career in ophthalmology. Prior to working on any research projects, students completed Collaborative Institutional Training Initiative (CITI) and electronic medical record (EMR) training.[17] The research staff created a manual and trained the students on the Wills' EMR system. After demonstrating proficiency, students utilized the EMR to recruit patients for active clinical trials and extract data for IRB-approved retrospective studies requiring ocular chart reviews. Students completed CITI training, which taught them how to identify, recruit, enroll, and retain human subjects in research studies. The CITI training also familiarized students with the Health Insurance Portability and Accountability Act (HIPAA) and its protection of patients' privacy. Students had the opportunity to obtain informed consent from patients during which they explained patients' rights as well as researchers' expectations in a clinical trial.

We also designed a 10-hour manuscript writing workshop series for enrolled students ([Table 3]). Training modules taught students how to conduct a literature review and use Endnote X5 software (Thomson Reuters, New York, NY). Students were assigned to an IRB-approved research project that was near completion and ready for the development of a manuscript. The students were allotted at least 6 to 8 hours per week for manuscript writing. Every 2 weeks, students delivered a newly written section of their manuscript, beginning with the introduction and continuing with the methods, results, and discussion sections. Several research assistants with writing experience served as peer editors and provided feedback at each juncture. The program director, research managers, and biostatistician offered ongoing feedback and reviewed the final manuscripts.

Table 3

Manuscript writing workshop and training schedule

Workshop

Topic

1

Electronic medical record training

2

Patient recruitment and data collection training

3

Conducting a literature review and EndNote training

4

Writing the introduction

5

Writing the research methods

6

Writing the data analysis

7

Writing the results

8

Writing the discussion

9

Developing an abstract and poster presentation

Source: Wills Eye Clinical Vision Research Training and Mentoring Program (used with permission, 2017).


During the last week of the program, students identified an appropriate peer-reviewed journal for manuscript submission (based on its impact factor and subject matter) and formatted their paper accordingly. With supervision from their mentor, who was usually identified as the corresponding author, they submitted manuscripts. Students also learned how to prepare an abstract for an ophthalmology-related conference, such as the Association for Research in Vision and Ophthalmology (ARVO), as well as how to develop a research poster. If a student's abstract was accepted for a conference, he or she had the opportunity to present the research findings and were often funded by the University or a conference research travel grant.

Enrolled students gained hands-on experience by having direct exposure to IRB-approved research studies. They played an active role in subject recruitment, consenting, data collection, and data analysis with our biostatistician. Students gained experience administering baseline research questionnaires and performed visual acuity testing, visual field testing, visual evoked potential testing, electroretinographies, and contrast sensitivity testing. They also participated in weekly, department-specific research meetings with their mentors, research coordinators, and managers. During these meetings, the research team offered project updates, discussed new studies relevant to the group's major research topics, and assigned readings to clarify the background and purpose of the clinical research studies underway ([Table 4]).

Table 4

Students' responsibilities

• Recruit patients for research studies

• Perform electronic medical records review

• Develop a mentoring relationship with a member of the Wills Eye research staff

• Work closely with mentors and trainers to complete assignments

• Attend lectures and workshops

• Review scientific literature to develop a manuscript

• Write a manuscript about the assigned research study

• Identify peer-reviewed journals for manuscript submission

• Format final manuscript for submission to a peer-reviewed journal

• Complete deadlines for assignments related to the manuscript

Source: Wills Eye Clinical Vision Research Training and Mentoring Program (used with permission, 2017).



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Mentorship and Core Attitudes

Mentorship was also a significant component of the clinical research program and a strong influence on students' attitudes toward vision research.[16] Each student was teamed up with a research mentor, with whom they met with several times during the summer. This relationship offered frequent contact, performance feedback, insight into diagnostic techniques and interpretation, and, in many cases, the potential for continuing research after the summer. Many students who engaged in clinical research at Wills Eye return independently during the academic year to follow up on projects. Often, these students are able to complete research manuscripts from the data they collected and receive publication credit for their contributions.

Students were encouraged to view their research projects in the context of patient experience. Therefore, clinical and surgical shadowing opportunities were offered. The degree of clinical participation varied by specialty, and students observed their mentor in the subspecialty clinic, operating room, or the Wills Eye Emergency Room. They learned the meaning of the data variables collected and analyzed, and consequently learned how to associate these values with patients' ocular conditions and treatments. Students had the opportunity to obtain informed consent from patients during which they explained patients' rights as well as researchers' expectations in a clinical trial. It is our hope that regular involvement with patients will reinforce the translational aspects of research and keep students mindful of the importance that patient-centered research can have on vision care.


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Pre- and Posttest Statistical Analysis

A pre- and posttest was administered to all students on the first and last days of the 8-week program. These tests consisted of 40 multiple choice questions within 11 topic areas and 3 to 4 questions were asked about each topic ([Table 2]). The test consisted of paired questions, so that the two tests were similar in difficulty and subject matter. A paired-sample t-test was conducted to compare scores using SAS 9.4 software (Statistical Analysis System [SAS] Institute, Cary, NC). This test was used to determine whether the mean difference between the two sets of observation is zero. The null cutoff p-value for detecting statistical significance was ≤0.05.


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Satisfaction Survey

The students completed an anonymous 10-question survey of their satisfaction with the overall program, including lecture series, manuscript writing workshop series, pre- and posttests, and mentor/trainer experience. Possible responses were on a 5-point Likert scale, with answers varying from strongly disagree to strongly agree. Means and standard deviations were assessed for each question.


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Results

Evaluation

Students scored statistically significantly higher on the posttest (mean [M] = 79.78%, standard deviation [SD] = 6.25) than on the pretest (M = 71.43%, SD = 8.43); p< 0.001. The largest improvement in scores was seen on the glaucoma, community outreach for glaucoma, vision and quality of life, transcorneal electrical stimulation, and IRB/consenting test sections (p < 0.001; [Table 5]).

Table 5

Pre- and posttest results: percentage of correct items (n = 34)

Covariate

Statistics

Pretest

n = 34

Posttest

n = 34

Parametric p-value[a]

General ophthalmology

n

34

34

0.239

Mean (SD)

84.71 (19.73)

79.41 (18.08)

Median

90

80

Min, Max

40, 100

40, 100

Glaucoma

n

34

34

<0.001

Mean (SD)

52.94 (28.23)

84.71 (18.46)

Median

60

80

Min, Max

0, 100

40, 100

Child vision screening

n

34

34

0.021

Mean (SD)

78.68 (23.14)

88.97 (15.31)

Median

75

100

Min, Max

0, 100

50, 100

Community outreach for glaucoma

n

34

34

<0.001

Mean (SD)

71.57 (32.96)

95.1 (11.98)

Median

83.33

100

Min, Max

0, 100

66.67, 100

Transcorneal electrical stimulation

n

34

34

<0.001

Mean (SD)

52.21 (22.5)

78.68 (21.44)

Median

50

75

Min, Max

0, 75

25, 100

IRB/Consenting

n

34

34

<0.001

Mean (SD)

64.71 (25.87)

88.24 (19.9)

Median

66.67

100

Min, Max

0, 100

33.33, 100

Statistics

n

34

34

0.148

Mean (SD)

69.61 (28.86)

58.82 (27.29)

Median

66.67

66.67

Min, Max

0, 100

0, 100

Diabetes and diabetic retinopathy

n

34

34

0.513

Mean (SD)

80 (17.75)

82.35 (14.58)

Median

80

80

Min, Max

20, 100

60, 100

Electronic medical records

n

34

34

0.074

Mean (SD)

92.35 (23.1)

79.41 (33.21)

Median

100

100

Min, Max

0, 100

0, 100

Smoking cessation

n

34

34

0.228

Mean (SD)

62.75 (17.91)

69.61 (22.27)

Median

66.67

66.67

Min, Max

0, 100

33.33, 100

Quality of life/SPARCS

n

34

34

<0.001

Mean (SD)

86.76 (19.69)

68.38 (21.59)

Median

100

75

Min, Max

25, 100

25, 100

Overall score

n

34

34

<0.001

Mean (SD)

71.43 (8.43)

79.78 (6.25)

Median

74.5

80

Min, Max

52.5, 82.5

64, 90

Abbreviations: IRB, Institutional Review Board; Max, maximum; Min, minimum; SD, standard deviation; SPARCS, Spaeth/Richman Contrast Sensitivity test.


a The parametric p-value is calculated by a paired t-test. Bold values indicate statistically significant.


Students strongly agreed that they were satisfied with the overall program and that the lecture series enhanced their learning (M = 4.6, using 5-point Likert scale). The lecture series (M = 4.6), the manuscript writing workshop (M = 4.6), and the editorial mechanisms for completing their manuscripts (M = 4.5) all received very favorable reviews ([Table 6]). We received several personal “thank you” notes via email and handwritten notes and have provided an example from a medical student:

Table 6

Program evaluations (n = 34)

Evaluation questions

M (SD)

I was satisfied with the program

4.6 (0.51)

Program goals and objectives were clear

4.3 (0.63)

Program was organized in a manner consistent with its stated goals

4.3 (0.68)

Pre- and posttest questions were fair

4.2 (0.82)

Adequate review mechanisms were provided for manuscript development

4.5 (0.56)

The course materials were valuable for learning

4.4 (0.73)

The lecture series and pre-residency lectures enhanced my learning

4.6 (0.60)

I was satisfied with the lecture series overall

4.3 (0.71)

The manuscript workshop series enhanced my learning

4.0 (0.80)

I was satisfied with the manuscript workshop series overall

4.6 (0.88)

The abstract and poster development sessions enhanced my learning

4.0 (0.79)

I was satisfied with the editorial/feedback process to prepare the manuscript

4.4 (0.67)

I was satisfied with the program supervision

4.5 (0.61)

Abbreviations: M, mean; SD, standard deviation.


Note: Scores range from 1 to 5 (1 = strongly disagree, 5 = strongly agree)


Source: Wills Eye Clinical Vision Research Training and Mentoring Program (used with permission, 2017).


Thank you for the opportunity to participate in the Vision Research Training and Mentoring Program this summer. It was a tremendous privilege to be a part of the wonderful research community at Wills Eye Hospital and especially in the Department of Research. I am grateful to have been a part of a program where students are given such trust and independence in their work. I treasure my experience this summer and look forward to continuing work at Wills in the future.

– Daniel Kim, MS2 at Sidney Kimmel Medical College


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Discussion

The Clinical Vision Research Training and Mentoring Program provided an evidence-based foundation in research methods and manuscript development for students pursuing degrees in medicine and public health. Students emerge with knowledge and skills to conduct vision research and understand basic ophthalmology. They also benefit from the support of a mentor in guiding their future career ambitions. The key strength of the Wills' approach is the vast amount of clinical vision research exposure that students gain over the course of the 8-week program. Students participate in all levels of research, from recruiting patients and gathering and analyzing data to preparing and submitting a manuscript. We hypothesize that this clinical research exposure enhanced students' core knowledge of ophthalmology and vision research skills.

Students in medical schools with traditional rigorous curricula often prefer to undertake research during the summer. Harvard University's Summer Program in Clinical Effectiveness fosters students' interest in research and provides tools for careers in academic medicine by teaching clinical research design and methodology.[18] Studies at the University of Tennessee and Vanderbilt University have examined the impact of student research fellowship programs over 25 years.[15] These programs offered mentored summer research experiences for first- and second-year medical students. A significant percentage of students performed further research, with one-third to one-half of graduates going on to pursue careers in academic medicine.[15] However, these summer research programs tend to be available only between the first and second years of medical school due to clinical rotation schedules.

The Wills Eye Program was more flexible and served not only medical students between their first and second years, but also has been abbreviated to a 1-month vision research elective format—without the lecture series and workshops—for medical students during their third or fourth year. Though created for medical students interested in applying to an ophthalmology residency, the program is easily adaptable for other specialties and may encourage research in any medical specialty. Students who decided to pursue another specialty after taking the program were able to apply basic research skills to any clinical research project.

Given that medical education programs leading to the MD/DO degree in the United States and Canada are accredited by the Liaison Committee on Medical Education (LCME), it is important to consider the recent update in LCME research requirements.[19] The LCME has created standards outlined in Functions and Structure of a Medical School, which medical schools must meet to achieve and maintain accreditation.[19] According to Standards IS-13 and IS-14, an institution that offers a medical education program should make available sufficient opportunities for medical students to participate in research and other scholarly activities of its faculty and encourage and support medical student participation.[19] Medical schools are required to describe the opportunities available for medical student participation in research, including the time periods when students may do so, the average number of students in the base year who were involved in each type of program, and the funding sources that are available to support student participation. The Wills Vision Research Training and Mentoring Program serves as a model for medical schools to successfully meet these LCME standards in the departments of ophthalmology, as well as other clinical and surgical departments.


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Study Limitations

In structuring the 8-week program, we had to sacrifice some of the depth and continuity of a typical clinical-research program. Since a research project can span months or years from concept to completion, 2 months may not allow students enough time to participate in the entire process. To address this limitation, we incorporated lectures and workshops that examined various research projects at different stages. Of the students enrolled in the 2014 program, six students chose to continue working with their research mentors and several undergraduate students returned the following summer prior to beginning medical school or after their first year of medical school. As this robust program was only recently established, no longitudinal data are yet available.


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Conclusion

This program provides an evidence-based foundation in research methods and manuscript development for students interested in careers in ophthalmology. It includes practical experiences for students and aims to enhance their knowledge of core program topics and improve their vision research skills. This pilot program can serve as a research training and mentoring model for ophthalmology and other medical and surgical specialties.


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Conflict of Interest

None declared.

Acknowledgments

The authors thank the Pennsylvania Department of Health for supporting the creation of the Vision Research Training and Mentoring Program for minority students in the summers of 2011–2013. This program served as the foundation of the current program. The authors also thank the Wills Eye Hospital Human Resources Department for assistance with the students.

Funding

None.


Ethical Approval

Ethical approval was granted by the Wills Eye Hospital Institutional Review Board on June 2, 2014 (IRB #14–388E).


Financial Disclosures

J.A.H is a consultant for Merck, Janssen, ThromboGenics, Novartis, and KalVista and a board member for Celgene. No other authors have financial disclosures.


Authors' Contributions

J.A.H., L.H., A.P.M., and E.J. conceived of the program and participated in its design and coordination. L.H., C.W., M.W., E.L.M., D.M.W., S.S., and K.S. acquired, analyzed, and interpreted the data, and drafted the manuscript. All authors critically revised the manuscript for important intellectual content and approved the final manuscript.


  • References

  • 1 Teo AR. The development of clinical research training: past history and current trends in the United States. Acad Med 2009; 84 (04) 433-438
    CrossrefPubMedGoogle Scholar
  • 2 Wyngaarden JB. The clinical investigator as an endangered species. N Engl J Med 1979; 301 (23) 1254-1259
    CrossrefPubMedGoogle Scholar
  • 3 Weinreb RN. Clinician-scientists in ophthalmology. Arch Ophthalmol 2001; 119 (02) 277-279
    PubMedGoogle Scholar
  • 4 Ley TJ, Rosenberg LE. The physician-scientist career pipeline in 2005: build it, and they will come. JAMA 2005; 294 (11) 1343-1351
    CrossrefPubMedGoogle Scholar
  • 5 Nathan DG. ; National Institutes of Health Director's Panel on Clinical Research. Clinical research: perceptions, reality, and proposed solutions. JAMA 1998; 280 (16) 1427-1431
    CrossrefPubMedGoogle Scholar
  • 6 Murillo H, Reece EA, Snyderman R, Sung NS. Meeting the challenges facing clinical research: solutions proposed by leaders of medical specialty and clinical research societies. Acad Med 2006; 81 (02) 107-112
    CrossrefPubMedGoogle Scholar
  • 7 Dickler HB, Korn D, Gabbe SG. Promoting translational and clinical science: the critical role of medical schools and teaching hospitals. PLoS Med 2006; 3 (09) e378
    CrossrefPubMedGoogle Scholar
  • 8 National Eye Institute 2017 Budget. National Institutes of Health. 2017. Available at: https://nei.nih.gov/news/congress . Accessed May 1, 2017
    PubMedGoogle Scholar
  • 9 Funding Mechanisms Supported by the National Eye Institute. National Institutes of Health. 2017. Available at: https://www.nei.nih.gov/funding/neifm . Accessed May 1, 2017
    PubMedGoogle Scholar
  • 10 Meyers FJ, Begg MD, Fleming M, Merchant C. Strengthening the career development of clinical translational scientist trainees: a consensus statement of the Clinical Translational Science Award (CTSA) Research Education and Career Development Committees. Clin Transl Sci 2012; 5 (02) 132-137
    CrossrefPubMedGoogle Scholar
  • 11 Alberts B, Kirschner MW, Tilghman S, Varmus H. Rescuing US biomedical research from its systemic flaws. Proc Natl Acad Sci U S A 2014; 111 (16) 5773-5777
    CrossrefPubMedGoogle Scholar
  • 12 Research Portfolio Online Report Tools (RePORT). National Institutes of Health. 2017. Available at: https://projectreporter.nih.gov . Accessed May 1, 2017
    PubMedGoogle Scholar
  • 13 Culican SM, Rupp JD, Margolis TP. Retaining clinician-scientists: nature versus nurture. Invest Ophthalmol Vis Sci 2014; 55 (05) 3219-3222
    CrossrefPubMedGoogle Scholar
  • 14 Dana R, Miller JW. On the edge: the clinician-scientist in ophthalmology. JAMA Ophthalmol 2013; 131 (11) 1401-1402
    CrossrefPubMedGoogle Scholar
  • 15 Solomon SS, Tom SC, Pichert J, Wasserman D, Powers AC. Impact of medical student research in the development of physician-scientists. J Investig Med 2003; 51 (03) 149-156
    CrossrefPubMedGoogle Scholar
  • 16 Yin HL, Gabrilove J, Jackson R, Sweeney C, Fair AM, Toto R. ; Clinical and Translational Science Award “Mentored to Independent Investigator” Working Group Committee. Sustaining the clinical and translational research workforce: training and empowering the next generation of investigators. Acad Med 2015; 90 (07) 861-865
    CrossrefPubMedGoogle Scholar
  • 17 Collaborative Institutional Training Initiative. CITI Course in the Responsible Conduct of Research. Ethics in Science and Engineering National Clearinghouse; 2000
    Google Scholar
  • 18 Summer Program in Clinical Effectiveness. Harvard School of Public Health. 2017. Available at: https://www.hsph.harvard.edu/clinical-effectiveness . Accessed May 1, 2017
    PubMedGoogle Scholar
  • 19 Functions and Structure of a Medical School: Standards for Accreditation of Medical Education Programs Leading to the MD Degree. Liaison Committee on Medical Education. 2015. Available at: http://lcme.org/publications . Accessed May 1, 2017
    PubMedGoogle Scholar

Address for correspondence

Lisa Hark, PhD, RD
Department of Research, Wills Eye Hospital
840 Walnut Street, Suite 802, Philadelphia
PA 19107   

  • References

  • 1 Teo AR. The development of clinical research training: past history and current trends in the United States. Acad Med 2009; 84 (04) 433-438
    CrossrefPubMedGoogle Scholar
  • 2 Wyngaarden JB. The clinical investigator as an endangered species. N Engl J Med 1979; 301 (23) 1254-1259
    CrossrefPubMedGoogle Scholar
  • 3 Weinreb RN. Clinician-scientists in ophthalmology. Arch Ophthalmol 2001; 119 (02) 277-279
    PubMedGoogle Scholar
  • 4 Ley TJ, Rosenberg LE. The physician-scientist career pipeline in 2005: build it, and they will come. JAMA 2005; 294 (11) 1343-1351
    CrossrefPubMedGoogle Scholar
  • 5 Nathan DG. ; National Institutes of Health Director's Panel on Clinical Research. Clinical research: perceptions, reality, and proposed solutions. JAMA 1998; 280 (16) 1427-1431
    CrossrefPubMedGoogle Scholar
  • 6 Murillo H, Reece EA, Snyderman R, Sung NS. Meeting the challenges facing clinical research: solutions proposed by leaders of medical specialty and clinical research societies. Acad Med 2006; 81 (02) 107-112
    CrossrefPubMedGoogle Scholar
  • 7 Dickler HB, Korn D, Gabbe SG. Promoting translational and clinical science: the critical role of medical schools and teaching hospitals. PLoS Med 2006; 3 (09) e378
    CrossrefPubMedGoogle Scholar
  • 8 National Eye Institute 2017 Budget. National Institutes of Health. 2017. Available at: https://nei.nih.gov/news/congress . Accessed May 1, 2017
    PubMedGoogle Scholar
  • 9 Funding Mechanisms Supported by the National Eye Institute. National Institutes of Health. 2017. Available at: https://www.nei.nih.gov/funding/neifm . Accessed May 1, 2017
    PubMedGoogle Scholar
  • 10 Meyers FJ, Begg MD, Fleming M, Merchant C. Strengthening the career development of clinical translational scientist trainees: a consensus statement of the Clinical Translational Science Award (CTSA) Research Education and Career Development Committees. Clin Transl Sci 2012; 5 (02) 132-137
    CrossrefPubMedGoogle Scholar
  • 11 Alberts B, Kirschner MW, Tilghman S, Varmus H. Rescuing US biomedical research from its systemic flaws. Proc Natl Acad Sci U S A 2014; 111 (16) 5773-5777
    CrossrefPubMedGoogle Scholar
  • 12 Research Portfolio Online Report Tools (RePORT). National Institutes of Health. 2017. Available at: https://projectreporter.nih.gov . Accessed May 1, 2017
    PubMedGoogle Scholar
  • 13 Culican SM, Rupp JD, Margolis TP. Retaining clinician-scientists: nature versus nurture. Invest Ophthalmol Vis Sci 2014; 55 (05) 3219-3222
    CrossrefPubMedGoogle Scholar
  • 14 Dana R, Miller JW. On the edge: the clinician-scientist in ophthalmology. JAMA Ophthalmol 2013; 131 (11) 1401-1402
    CrossrefPubMedGoogle Scholar
  • 15 Solomon SS, Tom SC, Pichert J, Wasserman D, Powers AC. Impact of medical student research in the development of physician-scientists. J Investig Med 2003; 51 (03) 149-156
    CrossrefPubMedGoogle Scholar
  • 16 Yin HL, Gabrilove J, Jackson R, Sweeney C, Fair AM, Toto R. ; Clinical and Translational Science Award “Mentored to Independent Investigator” Working Group Committee. Sustaining the clinical and translational research workforce: training and empowering the next generation of investigators. Acad Med 2015; 90 (07) 861-865
    CrossrefPubMedGoogle Scholar
  • 17 Collaborative Institutional Training Initiative. CITI Course in the Responsible Conduct of Research. Ethics in Science and Engineering National Clearinghouse; 2000
    Google Scholar
  • 18 Summer Program in Clinical Effectiveness. Harvard School of Public Health. 2017. Available at: https://www.hsph.harvard.edu/clinical-effectiveness . Accessed May 1, 2017
    PubMedGoogle Scholar
  • 19 Functions and Structure of a Medical School: Standards for Accreditation of Medical Education Programs Leading to the MD Degree. Liaison Committee on Medical Education. 2015. Available at: http://lcme.org/publications . Accessed May 1, 2017
    PubMedGoogle Scholar

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