Scientific competence during medical education - insights from a cross-sectional study at a German Medical School.

BACKGROUND: Medical knowledge regarding the pathophysiology, diagnosis and treatment of diseases is constantly evolving. To effectively incorporate these findings into professional practice, it is crucial that scientific competencies are a central component of medical education. This study seeks to analyse the current state of scientific education and students' desires for integration into the curriculum. METHODS: From October to December 2022, a survey was distributed at the Medical Faculty Dresden to all medical students from the 1st to 5th academic year (AY). The survey investigates current expectations of applying scientific competencies later in professional life, and the students were asked to self-assess various scientific skills and in relation to the National Competence Based Catalogue of Learning Objectives for Undergraduate Medical Education. The self-assessments were objectified through a competence test with ten multiple-choice questions. The desire for curricular teaching was inquired. RESULTS: 860 students completed the survey. This corresponds to a response rate of 64%. In the 5th AY, approximately 80% of the participants stated that they expected to work with scientific literature on a daily to monthly basis in future professional life and to communicate corresponding scientific findings to patients. Only 30-40% of the 5th AY rate their scientific competencies as sufficient to do this appropriately. This corresponds with the self-assessed competencies that only slightly increased over the 5 AYs from 14.1 ± 11.7 to 21.3 ± 13.8 points (max. 52) and is also reflected in the competence test (1st AY 3.6 ± 1.75 vs. 5th AY 5.5 ± 1.68, max. 10 points). Half of the students in the 4th and 5th AYs were dissatisfied with the current teaching of scientific skills. The majority preferred the implementation of a science curriculum (56%), preferably as seminars dealing with topics such as literature research, analysis, and science communication. CONCLUSIONS: The results show discrepancies between expectations of using scientific knowledge in everyday professional life, self-rated and objectively recorded competencies, and the current state of curricular teaching of scientific competencies. There is a strong need for adequate practical training, particularly in critical analyses of scientific literature, which enables the communication of scientific knowledge to patients.

Does the 'Educational Alliance' conceptualize the student - supervisor relationship when conducting a master thesis in medicine? An interview study.

BACKGROUND: Completing a master thesis (MT) is mandatory in many undergraduate curricula in medicine but a specific educational framework to guide the supervisor-student relationship during the MT has not been published. This could be helpful to facilitate the MT process and to more effectively reach the learning objectives related to science education in medicine. An attractive model for this purpose is the 'Educational Alliance' (EA), which focusses on the three components 'clarity and agreement on (a) goals, (b) tasks and (c) relationship & roles'. This study investigated factors that can either facilitate or hinder the process of MTs, and related these to the components of the EA. METHODS: We conducted semi-structured face-to-face interviews with 20 students and - separately - with their 20 corresponding supervisors, after the MT had been accepted. The interviews included open questions on factors facilitating or hindering the success of the MT. Audio recordings of the interviews were anonymized and transcribed, and then analysed by qualitative content analysis. Also, quantitative data were gathered on satisfaction with the MT process and the supervisory quality (using Likert-type questions). RESULTS: We were able to analyse all 40 interviews, related to 20 MTs. From the transcripts, we extracted 469 comments related to the research question and categorized these into the four main categories (a) 'Preparation', (b) 'Process', (c) 'Atmosphere', (d) 'Value of the MT'. Interviewees highlighted the importance of a careful preparation phase, clear expectations, a clear research plan, thorough and timely feedback, mutual agreement on timelines, and a positive working atmosphere. Each of these factors could be brought in line with the three components of the EA framework: agreement and clarity of goals, tasks, relationships & roles. Satisfaction with the MT process was rated 8.75 ± 1.22 SD (of 10) points by supervisors, and 7.80 ± 1.61 SD points by students, while supervision quality was rated + 1.51 ± 0.63 SD (scale from - 2 to + 2) by supervisors, and + 1.26 ± 0.93 SD by students. CONCLUSION: We propose the EA framework as a useful guidance for students, supervisors, and the university towards conducting successful MTs in medicine. Based on the findings, we provide specific recommendations for students, supervisors, and university.

New Jersey Leaves No Bite Behind: A Climate Change and Food Waste Curriculum Intervention for Adolescents in the United States.

Food waste is a major contributor to climate change. Schools offer a unique opportunity to educate on this issue while also reducing food waste generation; however, few climate-change education curricula that include a food waste component have been developed and tested with fidelity. Thus, the purpose of this cluster randomized controlled study was to assess the effectiveness of a climate change and food waste education program called NJ Leaves No Bite Behind (NJLNBB) among fifth-grade students. Lessons on food waste and sustainable food behaviors were developed that aligned with NJ Student Learning Standards for Climate Change and Next-Generation Science Standards. Participants (n = 162) completed pre- and post-test surveys that assessed knowledge, attitudes, self-efficacy, and behaviors. Post-test, the experimental group (n = 102) had significantly (p < 0.05) higher mean scores in knowledge, social norms, behavioral intentions, and perceived behavioral control compared to the control group (n = 60), with medium effect sizes, as determined by partial eta-squared. There were no significant between-group differences in mean score attitudes, self-efficacy, motivation to comply, or climate-friendly behaviors post-test. Almost three-quarters of participants who received the program agreed or strongly agreed the lessons were fun (75.5%), liked the card games (72.5), and learned a lot (78.4%). These findings are promising in terms of teaching adolescents the impacts of food waste on the climate.

Assessment of Knowledge and Attitudes on Genetically Modified Foods Among Students Studying Life Sciences.

BACKGROUND: Genetic engineering has stimulated interest in a range of fields, including agribusiness, food technology, food product development, and nutrition. Even though the public opinion on genetically modified (GM) goods is polarizing, the majority of experts believe that the advantages outweigh any potential risks, if at all there are any. As a result, the role of science education is to prepare students to be citizens who have a fundamental understanding of genetic engineering. As the students of life sciences are the future scientific experts and scholars who progress in the subject of genetically modified organisms (GMOs), they need to have correct knowledge of GMOs, GM foods, and appropriate attitudes regarding the same. METHODOLOGY: To investigate the knowledge and attitudes of life-sciences university students (n= 203) concerning GM foods, a cross-sectional observational survey-based study was carried out by administering a structured questionnaire across three disciplines of life sciences - Biotechnology, Food Technology, and Nutrition for undergraduates, postgraduates, and post-graduate diploma students. The scores for knowledge and attitudes were divided into tertiles as high, moderate, and low scores. RESULTS: 88.2% of the participants agreed to have read about GMOs in their curriculum and 76.8% had defined GM foods correctly. When the participants were categorized into tertiles, it was observed that out of all the high scorers, 45.5% were food technology majors and 43% were biotechnology majors and only 11.3% were nutrition majors. 63.1% of students were found to be in favor of GMOs and GM foods and had a positive attitude toward them. There was a moderately positive association of knowledge levels with attitudes toward GMOs and GM foods (p< 0.05). CONCLUSION: Although in general, the life-sciences students had the basic knowledge of GMOs and GM foods, the food technology, and biotechnology majors had better knowledge about GMOs and GM foods as compared to nutrition majors. The attitude scores were directly proportional to knowledge scores which emphasizes the need for robust science education on comprehending the topic better. Incorporating a GM-related curriculum for nutrition discipline can help students learn better about the issues surrounding transgenic technology, food safety, and nutrition.

The Fallacy of Teaching and the Illusion of Learning: Improving Articulation of Basic Science in the Medical School Curriculum.

Despite calls from educators to re-engineer how faculty deliver medical student curricula with integrated basic science concepts, this content is still frequently disarticulated from other curricular components. We renewed our curriculum using evidence-based pedagogical and cognitive learning strategies to interleave basic science across the 4-year curriculum.

The Role of Academia in Data Science Education.

As the demand for data scientists continues to grow, universities are trying to figure out how to best contribute to the training of a workforce. However, there does not appear to be a consensus on the fundamental principles, expertise, skills, or knowledge-base needed to define an academic discipline. We argue that data science is not a discipline but rather an umbrella term used to describe a complex process involving not one data scientist possessing all the necessary expertise, but a team of data scientists with nonoverlapping complementary skills. We provide some recommendations for how to take this into account when designing data science academic programs.

Most surface learning in the third year: Dental student learning approaches and implications for curriculum and assessment.

CONTEXT: Dental schools seek to educate students to become inclined toward self-directed, lifelong learning, an important mindset for healthcare professionals that may be linked to deep versus surface learning approaches. Students using a deep learning approach are more intrinsically motivated and actively engage in higher-order thinking, while those using a surface learning approach are more extrinsically motivated and aim for passive learning. OBJECTIVES: Because student learning approaches can be influenced by a wide variety of learning experiences, we sought to understand how student approaches to learning differ by year in dental school and are related to academic achievement. METHODS: A total of 244 students in a 4-year dental school program in South Korea voluntarily participated in this study. We collected data on school year and academic achievement, and approaches to learning of participants using the validated Study Processes Questionnaire to assess learning approach, which included the constructs of deep motive, deep strategy, surface motive, and surface strategy. RESULTS: We conducted 3 sets of statistical analyses and found that most students adopted a deep approach to learning (DAL) in their first and second years (Y1 and Y2), with third-year students (Y3) showing heavy dependence on a surface approach to learning (SAL) and sharp drops in intrinsic motives. Student approaches to learning were not significantly related to academic achievement. In the first 2 years of dental school, students tended to adopt a DAL, and viewed their learning as personal growth and their profession as necessitating deep intellectual inquiry. CONCLUSIONS: In the third year, the change from a DAL to a SAL coincided with entry to clinical training. The lack of integration of biomedical science (Y1 and Y2) and clinical science (Y3 and Y4), and increased stress in the initial clinical context may account for this difference. The poor correlation between a DAL and high achievement may indicate a need for change in assessment methods. This study hopes to stimulate reflection regarding student learning approaches and educational efforts that prepare future dentists for lifelong learning.

Patient-Centered Team-Based Learning in Pre-Clinical Curriculum Supporting the Application of Knowledge to Real-World Clinical Experience.

We report an active learning session which effectively supported 1st year medical students applying their learning experience in a clinical setting. A team-based learning (TBL) on familial hypercholesterolemia (FH) with a live patient was given to deliver basic genetics knowledge in a clinically relevant context. Subsequently, two participating students applied their learning experience by presenting a differential diagnosis of homozygous FH in a patient at a medical mission in Central America. We propose that combining active learning with clinically relevant scenarios effectively fosters student's clinical reasoning skills and can bridge the perceived gap between basic science and clinical education.

Authentic Literacy and Language (ALL) for Science: A Curriculum Framework to Incorporate Science-Specific Disciplinary Literacies into the Elementary Classroom.

Early elementary students are not typically introduced to science-specific disciplinary literacies - the specific ways in which scientists use and interpret language - even though authentic experiences with literacy strategies and tools used within the field may help incorporate learners into the scientific community of practice. The lack of freely available easy-to-use resources to build these literacies in the early elementary classroom may be a contributing factor. The Authentic Literacy and Language (ALL) for Science curriculum framework was developed as a deliberate approach to teach disciplinary literacies in the context of science using three distinct components: Science Investigations, Mini-lessons, and Science Inquiry Circles. Here we outline the development of the curriculum framework and a pilot of a 2nd grade unit based on the framework to teach concepts related to heredity and life cycles. We present findings from the pilot and discuss future directions and implications for the development and implementation of curricular materials using the ALL for Science curriculum framework.

Focusing a mobile science learning process: difference in activity participation.

The research on mobile learning in science lacks in-depth investigation of the learning process. In this paper, we describe the implementation of a mobile technology-supported science curriculum developed by design-based approach. The long-term data collection and trace of learning process enable the exploration of students' participation and identifying potential factors in mobile learning. Employing mixed research methods, the study presents the differences of students' engagement in mobile activity. It was found out that the participation of students in doing the mobile activities varied regarding the types of mobile tools, topics, class levels, and teacher feedback. The findings unfolded the factors affecting student activity participation behavior in mobile science learning and the problems encountered by the mobile science curriculum implementation. The results could potentially inform curriculum design and implementation supported by mobile technology, as well as support professional development of science teachers.

The inventory as a core element in the further development of the science curriculum in the Mannheim Reformed Curriculum of Medicine.

Introduction: The German Council of Science and Humanities as well as a number of medical professional associations support the strengthening of scientific competences by developing longitudinal curricula for teaching scientific competences in the undergraduate medical education. The National Competence Based Catalogue of Learning Objectives for Undergraduate Medical Education (NKLM) has also defined medical scientific skills as learning objectives in addition to the role of the scholar. The development of the Mannheim science curriculum started with a systematic inventory of the teaching of scientific competences in the Mannheim Reformed Curriculum of Medicine (MaReCuM). Methods: The inventory is based on the analysis of module profiles, teaching materials, surveys among experts, and verbatims from memory. Furthermore, science learning objectives were defined and prioritized, thus enabling the contents of the various courses to be assigned to the top three learning objectives. Results: The learning objectives systematic collection of information regarding the current state of research, critical assessment of scientific information and data sources, as well as presentation and discussion of the results of scientific studies are facilitated by various teaching courses from the first to the fifth year of undergraduate training. The review reveals a longitudinal science curriculum that has emerged implicitly. Future efforts must aim at eliminating redundancies and closing gaps; in addition, courses must be more closely aligned with each other, regarding both their contents and their timing, by means of a central coordination unit. Conclusion: The teaching of scientific thinking and working is a central component in the MaReCuM. The inventory and prioritization of science learning objectives form the basis for a structured ongoing development of the curriculum. An essential aspect here is the establishment of a central project team responsible for the planning, coordination, and review of these measures.

Trends in Basic Sciences Education in Dental Schools, 1999-2016.

The purpose of this study was to examine data published over the past two decades to identify trends in the basic sciences curriculum in dental education, provide an analysis of those trends, and compare them with trends in the basic sciences curriculum in medical education. Data published from the American Dental Association (ADA) Surveys of Dental Education, American Dental Education Association (ADEA) Surveys of Dental School Seniors, and two additional surveys were examined. In large part, survey data collected focused on the structure, content, and instructional strategies used in dental education: what was taught and how. Great variability was noted in the total clock hours of instruction and the clock hours of basic sciences instruction reported by dental schools. Moreover, the participation of medical schools in the basic sciences education of dental students appears to have decreased dramatically over the past decade. Although modest progress has been made in implementing some of the curriculum changes recommended in the 1995 Institute of Medicine report such as integrated basic and clinical sciences curricula, adoption of active learning methods, and closer engagement with medical and other health professions education programs, educational effectiveness studies needed to generate data to support evidence-based approaches to curriculum reform are lacking. Overall, trends in the basic sciences curriculum in medical education were similar to those for dental education. Potential drivers of curriculum change were identified, as was recent work in other fields that should encourage reconsideration of dentistry's approach to basic sciences education. This article was written as part of the project "Advancing Dental Education in the 21st Century."