Abstract
Background
Until recently, the outcome of medical students’ research projects has mainly been assessed in terms of scientific publications, whereas other results important for students’ development have been less studied. The aim of this study was to investigate medical students’ experiences of learning as an outcome of the research project course.
Method
Written reflections of 50 students were analyzed by manifest inductive content analysis.
Results
Three categories emerged: ‘thinking as a scientist’, ‘working as a scientist’, and ‘personal development’. Students became more aware about the nature of knowledge, how to generate new knowledge, and developed skills in scientific thinking and critical appraisal. Unexpectedly, effects on personal characteristics, such as self-confidence, self-discipline, independence, and time management skills were also acknowledged.
Conclusions
We conclude that individual research projects enhance research-specific skills and competencies needed in evidence-based clinical work and are beneficial for personal and professional development.
All doctors must understand the scientific process and must in their future practice be able to evaluate and integrate new knowledge (Citation1). Individual research projects are one way to develop these skills, and they are taking on a more central role in higher education, especially in medicine (Citation2).
Academic outcomes, for example, publications and presentations, have been measures of success of research project courses in medical education. Reports from three US medical schools show that 40–75% of the students had published at least one paper after their research period, and about half had given a presentation at an extramural meeting (Citation3, Citation4). Similar results have been reported by others and are presented in the most complete synthesis to date by Bierer and Chen (Citation2). However, publications in medical science are usually the result of teamwork and do not necessarily reflect the value of the research project course as a learning opportunity for the student.
By comparison, what medical students learn during research projects has been less studied. Several publications present only a description of the course, or experiences of the project administrators, albeit sometimes with students’ feedback (Citation1, Citation4–Citation8). Studies on students’ learning have often used questionnaires with scales and/or closed-end questions that limit respondents to a list of answers. Houlden et al. (Citation9) surveyed 60 medical students after a mandatory 8-week ‘Critical Enquiry’ course and found that half of the students experienced increased confidence in performing literature searches, critical appraisal, and manuscript preparation. Burgoyne and colleagues (Citation10) surveyed 317 medical students of whom 21% had taken or were currently taking a research-focused course, or had for a previous degree undergone a research program. The latter possessed significantly higher research-specific skills than the school-level entrants. As the study did not differ between students at different stages in their education, it is difficult to draw stringent conclusions about the learning benefits. A deeper analysis (Citation11, Citation12) based on interviews of 76 students from four colleges after a 10-week summer research program in, for example, physics, chemistry, or biology, showed increased confidence and gains in scientific knowledge and practical skills.
Experiential learning is referred to as learning through real-life experience emphasizing social interaction (Citation13, Citation14). Vygotsky described the zone of proximal development that represents the gap between the learner's developmental level in a certain task (what the learner can do without help) and the level that can be achieved with guidance by the ‘more knowledgeable other’ (e.g., supervisor) (Citation13). The core idea is that, with assistance, students are able to complete tasks that they are not able to do on their own (Citation15).
Another sociocultural theory of experiential learning focuses on communities of practice (COP) that are groups or networks in which the members, based on a common interest in a specific area, share knowledge and problems, and discuss and learn from each other (Citation16). Thus, students who do research projects in authentic COPs have access to expert knowledge, cooperation, and support, and thereby the opportunity to develop professionally and personally (Citation12, Citation17).
In summary, there is a lack of insight into student-defined learning as an outcome of longer research projects that are finalized with a formal, single-author scientific report. Such courses have become mandatory at medical as well as other university programs in Europe after implementation of the Bologna process. The aim of the current study was to investigate medical students’ experiences of learning and other outcomes of individual, advanced-level research projects, based on students’ written reflections after the course.
Methodology
Study setting
The educational context of this study is a medical university (Karolinska Institutet) with a 5.5-year long medical program. The program introduced a new curriculum in 2007. The first 2 years cover basic sciences (e.g., cell biology, anatomy, and physiology) and the last 3.5 years mainly clinical education (e.g., medicine, surgery, and pediatrics) including a total of 23 weeks of electives during the clinical courses. Three so-called threads (professionalism, primary care, and scientific education) run throughout the program. The mandatory course ‘Degree project in medicine’ (20 weeks; 30 European Credit Transfer System (ECTS) credits) was introduced in 2010 and placed in term 7. It constitutes the largest individual and most science-directed project that the students carry out, and was therefore considered a suitable context for this study. The overall aim of the course is to provide students with deeper understanding of performing and evaluating medical research. They individually, but under supervision, plan and carry out a research project and present a formal research report. The aim is not to train the students to become researchers or to write a paper for publication, but to bring them to understand the scientific basis of medicine and interpret scientific findings in order to become clinicians who are scientifically skilled. The scope of the final report is about 20–35 pages and the structure is similar to that of scientific papers. The target group is fellow students and other readers of scientific medical literature with basic medical education. The projects involve authentic empirical research in basic, clinical, or translational science, usually within a research group. The projects are supervised by an active researcher in the topic area and with at least a PhD degree. The first author of this paper was the course director for the course at the time of the study.
There are two mandatory checkpoints: seminars for presenting an initial project plan within the first 2–3 weeks and a midterm report. This creates two occasions for students to practice oral presentations and critical appraisal of other students’ presentations and reports. Another purpose is to jump start the writing process and for teachers to monitor the suitability and progression of the projects. The project plan includes a short introduction, aims, an overview of material and methods, and a few references. The midterm report consists of a preliminary version of the final report's introduction, aims, material and methods, and, if possible, some results, and a progress report on, for example, how far data collection and analysis have advanced as well as a time plan for the rest of the course. Both the project plan and midterm report are presented and peer-reviewed at separate seminars. The final examination comprises the complete written report, an oral presentation and critical appraisal of another student's report, and also a written reflection on personal experiences of learning and development during the course.
Study design
A qualitative approach was chosen for this study based on students’ written reflections of personal experiences of learning and development during the course. The theoretical starting point was the epistemological assumption that knowledge and understanding are socially constructed (Citation18). The current findings were the result of analysis of these reflections. Rather than reflecting an objective truth, the findings aim to contribute to the understanding of a complex phenomenon and to be reasonable and generalizable interpretations (Citation18, Citation19).
Material and sampling
Writing assignments that promote reflective capacity are becoming more common in medical schools. Dewey has claimed that reflection on experience belongs to the very heart of education, because education is basically the reconstruction or reorganization of experience (Citation20, Citation21). Many agree that reflection is associated with self-awareness and adult learning (Citation22–Citation24). Thus, written reflections are well-suited for the analysis of learning experiences.
In 2012, when data were collected, 122 of the 143 medical students turned in written reflections of 3–4 pages and based on three prompts: what the student learned during the course, the significance of collaboration, and what the student will take with himself/herself for the future. Responses to the first and third prompts were analyzed.
To obtain data, all 122 reflections were first read through by the first author, and texts rich in information and showing variation in learning experiences were selected (Citation25, Citation26). Initially, 20 content-rich reflections were selected for analysis, whereafter more were added until no new aspects emerged from the material (i.e., saturation was reached). In total, 50 reflections from students aged 24–48 were analyzed. Of these reflections, 45 were written in Swedish and 5 in English.
Data analysis
All the reflections were anonymized, and then numbered 1 to 50. Each reflection was analyzed separately. The anonymized reflections were the units of analysis and comprised 154 pages of text. The analysis was conducted using inductive manifest content analysis based on an iterative, constant comparison coding technique (Citation27, Citation28). Codes, subcategories, and categories were developed from the text without any predetermined coding scheme.
To obtain a sense of the whole, the reflections were first read through several times and then entered into the NVivo software package (Citation29) for coding. Then, meaning units were identified (Citation27). A ‘meaning unit’ was a statement that included one piece of information of interest for the aim of the study: it could be less than a sentence but never more than five sentences. The meaning units were read through several times and labeled with a code, and codes were grouped into subcategories according to their content. Finally, three main categories () were formulated to capture the manifest content. The study was approved by the Regional Ethical Review Board Karolinska Institutet, Stockholm, Sweden (Dnr 2010/1100-31/1 and Dnr 2011/493-32).
Results
This analysis of students’ reflections, regarding learning during the research project course, resulted in three main categories. These were: thinking as a scientist, working as a scientist, and personal development ().
Thinking as a scientist
The category thinking as a scientist is based on two subcategories that emerged from the reflections: the nature of scientific knowledge and attaining a scientific attitude.
The nature of scientific knowledge
Conducting a research project prompted students to reflect on the nature of knowledge. The epistemological perspective seemed to change to one that was more relative and complex than the students’ initial perspective. Students described how they came to realize that there is no absolute truth, and that today's knowledge is not necessarily the knowledge of tomorrow. One student commented:
Something I will take with me in the future is the realization that the information we have today, and on which our practices are based, need not be the absolute truth. (Student 8)
Another important insight for me has been how much painstaking work and research lies behind a few lines in a report, hours to months or years of work may lie behind a sentence in a scientific report. (Student 10)
Attaining a scientific attitude
A scientific attitude was found to entail critical thinking based on logical reasoning, inquisitiveness, and factual knowledge. The students realized that critical thinking and scientific attitude takes time to learn but can be developed by regular practice. The scientific attitude was seen to develop as a result of reading papers, critical appraisal of scientific texts, data collection, and scientific writing.
By combining my logical reasoning with my medical knowledge and inquiry as a starting point when reviewing recent literature, I ended up using critical thinking skills automatically. What I also discovered was that this is a mindset that can be developed just like any other skill; Like any other skill you must practice it regularly. (Student 35)
… Serious critical thinking should not only be practiced by researchers …. I also became convinced about the importance of using it in clinical practice in the future, where the ability to discern truth from modified truth is valuable. (Student 35)
Working as a scientist
This category was based on three subcategories: scientific research in practice, scientific information competency, and scientific communication.
Scientific research in practice
The core of this subcategory is the students’ descriptions of the practical research process, about which they knew little before the course. Previous teaching in science had been theoretical and had included only short practical exercises, whereas the research project course allowed students to learn the craft, from planning to writing a report in an authentic environment.
The main thing I have learned, I believe, is the actual realization of how the scientific process works and how to initiate, plan and implement a project of this size in practice. (Student 43)
Solving problems, and looking at a problem in a new way, solving it, finding new ways, trying them, failing, continuing and trying a new way, failing again, trying something new that might succeed … this is the heart of research. (Student 38)
The image ordinary people probably have is that of a lonely researcher who works hard for himself in a half-dark lab in the evenings, finally crying ‘Eureka!’ not surrounded by anyone …. This picture could not be more wrong. Research requires collaboration ALL the time. (Student 32)
I have had many discussions during the semester with various scientists about their views on the world of research and realized that it is largely a cynical world. (Student 30)
Scientific information competency
It appeared that literature searches progressed from substandard or routine searches to more focused and effective ones. Students learned to build and use search strategies in different databases wherefore their ability to manage information overload improved. Experiencing an improved ability to find relevant information also increased the desire to seek new information.
It is easier for me to use all the databases that are available. I feel that I can better manage the abundance of available information and select information for a specific purpose. (Student 6)
I have previously felt scientific papers in English were complicated and difficult to understand, so I often neglected to read them. During this semester, I have really put my ‘fear’ of scientific papers to the test and worked out a technique to read them. Now it feels perfectly natural to seek current knowledge in scientific articles. (Student 4)
Critical review of scientific texts is perhaps the most important thing I learned and what I will use the most in everyday clinical practice in the future. (Student 20)
Scientific communication
Scientific writing – the ability to write clearly, objectively, concisely, and without emotional expressions – was considered difficult and time-consuming. Students stated that it was like learning a new language: the more one practices, the easier it gets. They also discovered that the more they read, the easier it became to write. In addition to reading and analyzing the language in the papers, writing skills were developed by discussions with supervisors and classmates, oral presentations, peer review for seminars, and continuous feedback. The students gradually learned that scientific writing is a process.
Over time, I learned that you go back and change all the time. That writing is a process that takes time. You change your text. You make it better. In the beginning, I tried to imitate the way language is used in the articles, but towards the end I stopped checking. I had begun to think in a different way, and therefore also write in a different way. (Student 13)
It was very different from previous presentations, which usually have involved a certain topic or a disease. Now it was instead one's own work with own questions and reflections and own results and interpretation of these. It was exciting and at the same time a little challenging …. (Student 50)
To listen to others who present their projects, to discuss, to receive criticism, and to defend one's own work has been developing. It has also helped me to progress in my project by bringing up new thoughts and ideas. (Student 37)
By discussing my work with my friends and family, or rather telling them about it, I have deepened my own understanding of the subject, become better at communicating in an understandable way, and developed the ability to pay attention to what might be difficult to understand for those not familiar with the subject. (Student 25)
Personal development
The most salient learning outcomes and benefits were related to personal development. This category included five subcategories: self-confidence, independence and collaboration, time management, self-discovery, and career planning.
Self-confidence
Students gained self-confidence not only regarding their ability to do scientific research but also their future work as a physician. Increased self-confidence was related to successful experiments or other results, to the ability to solve problems, and to the overall ability to carry out a project.
During my time in the lab I developed good self-confidence in terms of my ability to pursue research. I feel today more convinced that I possess the combination of knowledge, skills, and curiosity that are necessary to conduct research. (Student 27)
Independence and collaboration
Students learned to work independently and experienced that they had to take responsibility for the whole project. The development of independence was described as a process. It was initially distressingly difficult to know what to do and how to proceed, but the subsequent process toward independence enhanced the students’ motivation and ownership of the project. Altogether, this was considered valuable for their future professional work.
I have learned that I have the sole responsibility for what I do. I think this is also important for the future work with the patients. It is my responsibility to know what to do for my patients. (Student 5)
I have learned what a positive environment a lab can be. The eagerness of my fellow labworkers to help me has rescued me from many tricky situations I think such environments, in which everyone shares their knowledge and helps each other, are important for the scientific community and benefit everyone. (Student 33)
Time management
Time management skills regarding activities related to research, and students’ personal life, improved. These skills included ability to allocate time; set goals; and organize, schedule, and prioritize activities, both on a daily and on a long-term basis. An important discovery was that things take longer time than expected. Students described how they also had to learn to take into account their supervisors’ schedules. Overall, students felt that time management skills were worth developing for their future profession.
This term has brought planning to a new level …. I created my own schedule in order to finish my report. This schedule included meetings with supervisors and other key persons … with limited timeframes, so I also had to develop the ability to use time during these meetings in a very efficient manner. (Student 37)
Self-discovery
During the semester, I also learned about myself: I aminterested in people, and want to help people andconnect with other people. This has reduced mydoubts about medicine being the right choice for me.(Student 24)
The traits essential for a successful scientist are perseverance and patience, two qualities that do not necessarily define me. (Student 49)
I have also, with the help of my supervisor, learned to handle what might have been the hardest part of the project work, to fail. At first it was very difficult for me …. I have now learned that failed experiments are common when doing basic research. (Student 27)
Career planning
Although research as an option for the students’ future profession had been unclear before the course, almost all students wrote that their career plans now included a wish to do research. The most common notion was to become a part-time clinical researcher; the possibility to combine clinical work with part-time research was a positive surprise and opened up for new career plans.
When I started medical school, it was in some way the researcher's role I was curious about, but I quickly pushed it aside after understanding that my interest mainly lies in the clinical work. Now, however, I realized that the one does not exclude the other. (Student 18)
I also became interested in teaching. Thanks to my supervisors who have shown that it is possible to work clinically, do research and teach, I also became interested in combining all these three parts. (Student 40)
The stimulus it provides to listen to people's life stories, help them with their ailments, and diagnose diseases is undoubtedly superior to working as a junior researcher – even in a top-down, flow-fixed health care organization. (Student 45)
Discussion
This study is one of the few studies that focus on outcomes, in terms of learning, of the increasingly common one-term mandatory research project courses for medical students. Rather than assessing the number of resulting publications, which has been done in several previous publications (Citation2, Citation30), the study reports outcomes as revealed by qualitative analysis of students’ own written reflections. Importantly, our results thus relate to the students’ own perspective and indicate corollaries that may be of consequence for their future profession. The reflections show that research-related skills developed in alignment with the intended learning outcomes. A major finding was, perhaps unexpectedly, that the students placed such emphasis on the impact on personal development.
In the past, basic professional education was sufficient for a lifetime career. Our results indicate that the research project course helped students realize that today's physicians need to remain scientifically updated and that scientific knowledge is dynamic, not static. As a course outcome, the emergence of such an understanding has not often been reported in the literature, but is consistent with a study on college students by Seymour et al. (Citation11). Along with improved confidence in, for example, critical appraisal of scientific information, this understanding is a prerequisite for intellectual progress and scientific attitude.
We place our findings within the framework of experiential learning (Citation13, Citation14) and the notion that knowledge and understanding are socially constructed (Citation18). The present results support and illustrate the educational functions and benefits of acting within a COP (Citation16). We find it significant that although not asked to, the students described their learning processes, for example, how discussing science with people within as well as outside the research team supported development of communication skills as well as personal scientific understanding. We noted that this was experienced within quite different COPs (data not shown).
Our findings indicate other generic skills and insights as outcomes of the course, notably development of independence, in terms of responsibility both for the project and for own learning needs, time management, and increased self-knowledge. These findings along with the above aspects of personal development were not the result of theoretical studies but important steps toward a structured and rational mindset that were conveyed and nurtured by social interactions in a research context (Citation13–Citation15). We therefore encourage all attempts to increase the awareness among supervisors of their crucial roles as role models and communicators.
However, none of the students indicated a connection between improved communication skills and clinical work, for example, communication with patients or other health care workers. Similarly, neither increased teamwork skills nor the importance of teamwork in science were associated with the future professional work. These findings are new though not very encouraging. They may, however, depend on the prompts; it would be interesting to investigate responses to prompts that more specifically address these issues, in particular as communication and teamwork skills in clinical environments are related to increased patient safety and health care efficiency (Citation31). We therefore suggest that practicing teamwork and communication during research projects should be more explicit learning outcomes, which would further strengthen the link between scholarly work and clinical education.
Research training during medical schools has been suggested to increase interest in research careers (Citation32, Citation33). Quantitative studies have examined this by reporting percentages of students aiming for research careers (Citation2). Our study, in concordance with a few others (Citation34, Citation10), shows that as students become more aware of research and its relevance for medicine they also start involving research in their career plans. Surprisingly, many students had been unaware that engaging in research does not exclude clinical work but exposure to research is likely not enough to establish it as career choice. Based on social cognitive theory, Bakken and colleagues (Citation35) suggested that person–environment interactions as well as outcome expectations shape learning experiences and career choices. Thus, supervisors as role models and students’ capability to cope with uncertainty, stress, and anxiety during the research project may, among other factors, impact career choices. These aspects have not been investigated in the current study. We believe, however, that medical students constitute an important source of future researchers wherefore research projects courses may well encourage scientific careers.
Mandatory research training in medical education is sometimes criticized for usurping time and effort in an already overloaded curriculum (Citation34). In addition, students’ research projects often appear as a final-year assessment when students are expected to show a mastery of their discipline. Our findings indicate long-term personal and professional benefits of a research project course and support placing it earlier in the education; this enables students to implement their experiences during the final clinical education, and to further appreciate the value of social interaction in a good COP (Citation14, Citation15). In addition, as many students came to realize the need to question and evaluate information and tradition, the course may enhance the understanding of the connection between optimal patient care and evidence-based medicine; this is another interesting subject for further investigation.
Several limitations warrant a discussion. First, credibility (Citation19, Citation27) may be questioned in that students’ descriptions are subjective, and may be anywhere on a scale between ‘genuine’ and ‘dishonest’ (Citation36). Most students wrote their reflection during the examination period, which may have caused stress and thereby immoderate feelings. However, both positive and negative aspects were revealed, indicating that students felt comfortable enough to express their true reflections. Moreover, the reflections were anonymous. In order to add credibility, we used a comprehensive sampling providing a variety of participants and breadth in the data. Investigator triangulation was used engaging all authors in the analysis. The coding and the definition of categories have been discussed and checked by all the authors. To attain dependability, the data were collected until no new categories emerged (saturation) and were continually re-examined using the insights that emerged during analysis. Finally, this study has been conducted at one university wherefore the context has been described at some length (Citation27). This enables the reader to evaluate transferability to other settings.
Altogether, the results illustrate that individual research projects may be beneficial for both personal and professional development. Future studies should investigate supervisors’ perceptions of students’ learning, supervisor–student relationships, and their impact on learning, and examine the roles of the different learning environments at hand and the impact of research project courses on the numbers of MDs and PhDs.
Conflict of interest and funding
The authors report no conflicts of interest.
Authors' contributions
All authors (RM, MS, and KH) have read and approved the final manuscript.
Acknowledgements
We are indebted to Klara Bolander Laksov and Charlotte Silén for comments on study design and theories. This work was supported by Karolinska Institutet's funding for educational projects, and Karin and Nils Rosander's Donation Fund.
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