Undergraduate medical education.

Pressures from students and teachers, from professional bodies, and from changes in the way health care is delivered are all forcing a rethink of how medical students should be taught. These pressures may be more intense in London but are not confined to it. The recommendation the Tomlinson report advocates that has been generally welcomed is for more investment in primary care in London. General practitioners have much to teach medical schools about effective ways of learning, but incentives for teaching students in general practice are currently low, organising such teaching is difficult and needs resources, and resistance within traditional medical school hierarchies needs to be overcome. Likewise, students value learning within local communities, but the effort demanded of public health departments and community organisations is great at a time when they are under greater pressure than ever before. The arguments over research that favour concentration in four multifaculty schools are less clear cut for undergraduate education, where personal support for students is important. An immediate concern is that the effort demanded for reorganising along the lines suggested by Tomlinson will not leave medical schools much energy for innovating.     

Undergraduate and postgraduate medical education in Canada

An overview of medical education at both the undergraduate and postgraduate levels in Canadian faculties of medicine is provided. Particular attention is focused on changes that have occurred in the 1990s and their effect on medical students and on educational programs. Also considered are the effects of reductions in the number of entry-level positions for residency training and the changes in educational requirements for licensure on senior medical students.     

Undergraduate geriatric education through community service learning

doi: 10.1111/j.1741‐2358.2010.00444.x Undergraduate geriatric education through community service learning Introduction: Despite the exponential growth of the elderly population worldwide, geriatric education has been a formal component of only a few dental schools’ curricula. Objective: To describe the geriatric community service learning (CSL) component of the professionalism and community service (PACS) module, and to explore a CSL project carried out by a group of first year dental students at a long‐term care facility. Methods: A literature review was performed to present and describe the CSL component of the PACS module. Students’ personal reflections were used to illustrate some of the joys and challenges of experiencing a long‐term care facility environment. Results: The newly developed PACS module combines community service learning with the long‐term care experience. Students develop, apply and evaluate an educational health promotion activity in a long‐term care facility. Conclusions: The PACS module has encouraged students to acquire comprehensive knowledge and awareness of the needs and dynamics of a long‐term care as they collaboratively interacted with personnel from the facility to develop their projects. The authors would like to engage other schools in discussing the need to integrate community‐based geriatric education into their dental curricula.     

Undergraduate education in gerodontology in Germany: the Leipzig Programme

Objective: To evaluate students’ attitude towards the clinical component of the Leipzig Programme of undergraduate Education in Gerodontology (LPEG). Background: Undergraduate student education has long been recognised as a mainstay of fostering the aims of gerodontology. Extramural clinical education with direct exposure to various groups of vulnerable elderly is known to contribute to the formation of positive attitudes. LPEG has been designed to include didactic components and six visits to a long‐term care facility (LTC) spread over 4 of the 5 years of the dental course. Methods: A structured questionnaire with 10 items was administered to 230 students (60.9% female) on three occasions in 2004–05. Total return was 411 questionnaires. The mean age of respondents was 24.3 (SD 2.67) years. Students were asked to indicate the degree of their agreement with seven statements presented using a 5‐point scale. A choice of responses which characterised the course was offered to mark all those deemed agreeable. Results: The vast majority of students responded positively. In the students perception there was no significant difference (Kruskal–Wallis p = 0.24) in the amount of knowledge acquired between subjects participating once, twice or three times. ‘Interesting’ and ‘feel pity for patients’ were the two items that received the most support. Respondents expressed the wish to accompany up to 10 patients during their course with a mean of 3.5 (SD 2.9) but 31 (7.5%) subjects did not wish to see any frail elderly patients at all. Conclusion: The LPEG is well received by dental students. A complex subject including overarching social skills has been integrated seamlessly into the dental curriculum.     

Innovations in human genetics education. Medical student elective in clinical genetics.

The fourth-year medical student elective in clinical genetics has been enhanced by the addition of a problem-solving project. The assignment requires students to pose and answer a practical question about a professionally relevant genetic problem. Exemplary questions and the details of the exercise are given. Six of 10 students choosing an elective in clinical genetics have undertaken the project. Their feedback suggests that the requirements of decision making, library research, discussion with consultants, and medical writing in a limited time period are beneficial additions to the standard elective.     

Undergraduate structural biology education: A shift from users to developers of computation and simulation tools

The use of theory and simulation in undergraduate education in biochemistry, molecular biology, and structural biology is now common, but the skills students need and the curriculum instructors have to train their students are evolving. The global pandemic and the immediate switch to remote instruction forced instructors to reconsider how they can use computation to teach concepts previously approached with other instructional methods. In this review, we survey some of the curricula, materials, and resources for instructors who want to include theory, simulation, and computation in the undergraduate curriculum. There has been a notable progression from teaching students to use discipline-specific computational tools to developing interactive computational tools that promote active learning to having students write code themselves, such that they view computation as another tool for solving problems. We are moving toward a future where computational skills, including programming, data analysis, visualization, and simulation, will no longer be considered an optional bonus for students but a required skill for the 21st century STEM (Science, Technology, Engineering, and Mathematics) workforce; therefore, all physical and life science students should learn to program in the undergraduate curriculum.