Extended reality anatomy undergraduate teaching: a literature review on an alternative method of learning

Smart glasses use experience of nursing graduate students: qualitative study

BACKGROUND

Immersive technologies such as smart glasses can benefit nursing training and clinical practice. In this paper, we explore the views of nursing graduate students about their experience with smart glasses.

METHODS

Nursing graduate students (n = 13) were recruited using purposeful sampling. First, a virtual reality intervention for hyperglycemia in nursing care was shown. This was an attempt to introduce people to the technology and start discussions about how it might be used in nursing care. After that, participants underwent online interviews. Thematic analysis was used to examine the data.

RESULTS

The study findings indicated that the use of smart glasses as an enjoyable learning experience and immersive games positively affects nursing students. In addition, it was determined that they had negative experiences such as costs, lack of infrastructure, and smart glass side effects.

CONCLUSIONS

Smart glasses indicate good usability and availability in nursing education and potential for use in hospital nursing practice.

The combined effects of an anatomy program integrating drawing and gamification on basic psychological needs satisfaction among sport sciences students: Results of a natural experiment

According to self-determination theory, the need for competence, autonomy, and relatedness has been associated with intrinsic motivation. Fulfilling basic psychological needs can lead to better learning, academic performance, and well-being. In this study, an anatomy program integrated gamification and drawing methods to explore their influence on basic psychological needs satisfaction and potential learning implications. Basic psychological needs outcomes of sport sciences students were compared to test the effects of the Observe-Reflect-Draw-Edit-Repeat (ORDER) method and gamification (experimental condition) versus a non-ORDER and non-gamified program (control condition). These two different 30-h (7-week) anatomy education programs were implemented at two Spanish public universities with 116 first-year sport sciences students. Pre and post-treatment measurements were collected using the Basic Psychological Needs Satisfaction Scale. Statistical analyses included independent samples t-tests, ANCOVAs, and factorial repeated measures ANOVAs 2 × 2 (time × treatment). The gamified ORDER program achieved higher satisfaction scores in basic psychological needs compared to the control group (t = 2.98, p = 0.004, d = 0.54). Additionally, an interaction effect between time and treatment was observed (p = 0.042,η p 2  = 0.038). Treatment and interaction effects were observed for 'autonomy' (p = 0.003,η p 2  = 0.074) and 'competence' satisfaction (p = 0.048,η p 2  = 0.035). A time effect was found for 'relatedness' in the control group, but no significant treatment or interaction effects were identified. The causes of these effects are debated in the study, as well as the limitations. These findings support the notion that students' basic psychological needs are better satisfied in anatomy education with the implementation of this multimethod educational intervention based on ORDER and gamification.

Investigation of factors that influence the relationship between mental rotation ability and anatomy learning

BACKGROUND

Mental rotation is a cognitive process that involves the rotation of a mental representation of an object. This ability is important for medical students in studying anatomy as this subject requires the understanding of positional relations between organs.

OBJECTIVES

To find the effect of video learning of anatomy, training, gender, and type of practical exam on mental rotation ability. Also, to find correlation between mental rotation and anatomy scores.

METHODS

Two groups were recruited: group A studied practical anatomy online using videos due to the COVID-19 pandemic lockdown; group B studied anatomy labs on-campus on plastic models. Both groups underwent a mental rotation test. Group A took labs on-campus during their second year and this was considered a training course for their mental rotation ability. Both groups, then, took a second mental rotation test. Group A was finally given a practical anatomy exam using plastic models.

RESULTS

Males scored higher than females, though not significantly. The intervention course produced no significant change in mental rotation score of group A. Mental rotation score was correlated more with the theoretical anatomy exams than the MCQ-based practical exam, for both groups. For group A, mental rotation was better correlated with the model-based than the MCQ-based practical exam, especially the post-training score.

CONCLUSION

For students to take full advantage of their mental rotation ability, not only their practical anatomy sessions but their practical anatomy exams should be on anatomical specimens and not just videos or images.

The influence of collaborative learning and self-organisation on medical students' academic performance in anatomy

BACKGROUND

In 2021, university teaching at the Faculty of Medicine Tuebingen was transferred to a digital setting. Due to the discontinuation of face-to-face teaching, students lacked the temporal and spatial framework of the curriculum and the possibility to socialise with fellow students was extremely limited. Increased demands were placed on the students' self-organisation, and the possibility of collaborative learning was drastically limited. The present study investigated the extent to which these study conditions affected the academic performance of medical students in the oral exam after the 60-hour introductory anatomy lecture. Specifically, collaborative, and organisational learning strategies were considered.

METHODS

Learning strategies of 146 students were assessed by means of a questionnaire. The anatomy exam was used to assess the academic performance. In addition, students were asked to rate their own oral exam performance.

RESULTS

Students used strategies of collaborative learning (M = 3.30, SD = 0.88) and self-organisation (M = 3.28, SD = 0.72) about equally as often. A significant correlation was found between the use of collaborative learning strategies and the ability for realistic self-assessment (ρ = -0.22, P =.02). Collaborative behaviour could be divided into Initiative Collaborative Learning and Subordinate Collaborative Learning. Only the former had an influence on the ability for realistic self-assessment. Neither organisational learning strategies nor collaborative learning strategies had an influence on academic performance.

DISCUSSION AND CONCLUSION

Initiative collaborative learners showed a higher degree of realistic self-assessment. This could be explained through a more distinct social referencing, as fellow students' knowledge levels can be related early on to their own academic performance. There was no correlation between the learning strategies used and the exam result.

United Kingdom medical student expansion - Can new medical schools seize the initiative?

In June 2023, National Health Service (NHS) England published a Long-Term Workforce Plan 'to put staffing on a sustainable footing and improve patient care.' The plan falls in to three main areas: train, retain and reform. Currently there are around 7,500 medical school places available annually in England, but it is proposed to increase this to 10,000 by 2028 and to 15,000 by 2031. Five new medical schools were approved in the 2018 expansion and others are preparing applications in anticipation of future expansion. In this article, we discuss what factors might shape a new medical school, ensuring it meets the standards required by the UK regulator (General Medical Council) set out in Promoting Excellence and in Outcomes for Graduates.

[Emergencies-Infinite worlds? : Extended reality as a medium in the education, continuing and advanced training in emergency medicine]

BACKGROUND

Simulation training is indispensable in emergency medicine, especially for enhancing patient safety. Methods and technologies used include a wide spectrum ranging from simple skill trainers to complex full-scale simulated environments integrating standardized patient actors. Limitations include the simulation of dynamic changes of clinical symptoms, the depiction of emotions and patient movements as well as complex environments, such as lively traffic. Extended reality (XR) holds the potential to overcome these limitations.

METHODS/AIMS

Starting with the technological basis and the didactic considerations in the field of XR, the paper reflects the potentials and limitations of this new technology in the domain of medical simulation training. Further focus is put on the integration of XR into existing training curricula.

RESULTS

The XR covers various technologies, ranging from PC-based applications that are similar to conventional computer games, over virtual realities enabling spatially freely navigable 3‑dimensional simulation (using closed 3D glasses: head mounted displays, HMD), to mixed-reality applications that combine virtual elements and real physical objects; however, technology alone does not stimulate learning. As with other simulation methods, it is crucial with XR to implement learning objectives, methods and technologies in a suitable teaching-learning arrangement and to familiarize teachers and students with the new technology. Evidence in the literature with respect to learning success is limited by the heterogeneity of technologies, target groups, teaching-learning arrangements and learning outcomes. Overall, significant increases can be shown for the intrinsic motivation of learners, and for high emotional participation (measured as perceived presence in the virtual environment).

DISCUSSION

Technological developments and the increasing use of digital media in emergency medical education and training favor the leap from XR-based pure demonstration projects to educational practice. Decisive for the educational success are the clear orientation towards concrete learning goals and a thorough familiarization with the new technology.

CONCLUSION

Simulation training based on XR expands the spectrum of existing simulation methods to integrate new dimensions of learning objectives. Further research on the effectiveness of this method is needed.

Online interactive medical neuroimaging exercise to identify human brain structures

A persisting need remains for developing methods for inspiring and teaching undergraduate medical students to quickly learn to identify the hundreds of human brain structures, tracts and spaces that are clinically relevant (viewed as three-dimensional volumes or two-dimensional neuroimages), and to accomplish this with the option of virtual on-line methods. This notably includes teaching the essentials of recommended diagnostic radiology to allow students to be familiar with patient neuroimages routinely acquired using magnetic resonance imaging (MRI) and computed tomography (CT). The present article includes a brief example video plus details a clinically oriented interactive neuroimaging exercise for first year medical students (MS1s) in small groups, conducted with instructors either in-person or as an entirely online virtual event. This "find-the-brain-structure" (FBS) event included teaching students to identify brain structures and other regions of interest in the central nervous system (and potentially in head and neck gross anatomy), which are traditionally taught using brain anatomy atlases and anatomical specimens. The interactive, small group exercise can be conducted in person or virtually on-line in as little as 30minutes depending on the scope of objectives being covered. The learning exercise involves coordinated interaction between MS1s with one or several non-clinical faculty and may include one or several physicians (clinical faculty and/or qualified residents). It further allows for varying degrees of instructor interaction online and is easy to convey to instructors who do not have expertise in neuroimaging. Anonymous pre-event survey (n=113, 100% response rate) versus post-event surveys (n=92, 81% response rate) were attained from a cohort of MS1s in a neurobiology course. Results showed multiple statistically significant group-level shifts in response several of the questions, showing an increase in MS1 confidence with reading MRI images (12% increase shift in mean, p<0.001), confidence in their approaching physicians for medical training (9%, p<0.01), and comfort levels in working online with virtual team-based peers and with team-based faculty (6%, p<0.05). Qualitative student feedback revealed highly positive comments regarding the experience overall, encouraging this virtual medium as a desirable educational approach.

Application of Blended Learning to Veterinary Gross Anatomy Practical Sessions: Students' Perceptions of Their Learning Experience and Academic Outcomes

The use of blended learning strategies is increasingly common in health sciences, including veterinary medicine; however, there are very few descriptions of these methods being applied to practicals. We describe here the application of blended learning based on the implementation of flipped classrooms with collaborative learning and gamification to the 2020-2021 veterinary medicine gross anatomy practicals at CEU Cardenal Herrera University (Spain). Students prepared for the sessions by pre-viewing videos and taking a quiz before the start. The sessions were conducted in small groups where students learned through collaborative work and reviewed their learning with a card game. A small but significant increase was observed when comparing the scores of practical exams of the locomotor apparatus with those of 2018-2019 (6.79 ± 2.22 vs. 6.38 ± 2.24, p < 0.05), while the scores were similar (7.76 ± 1.99 vs. 7.64 ± 1.92) for the organ system exams. Students' responses in a satisfaction survey were mostly positive (>80%) regarding the motivating and learning-facilitating effect of this educational method. Our work shows that the application of blended learning in anatomy practicals based on a flipped classroom and with elements of gamification and collaborative work can be an effective way to improve the learning experience of students.

The relationship between visual memory and spatial intelligence with students' academic achievement in anatomy

INTRODUCTION

Academic achievement is influenced by various factors. Spatial intelligence and visual memory are among the factors that seem to be related to learning anatomy. The aim of this study was to investigate the relationship between visual memory and spatial intelligence with students' academic achievement in anatomy.

METHODS

The present study is a descriptive cross-sectional study. All medical and dental students who had chosen anatomy courses (Semester 3 medicine and 2 dentistry) were the target population (n=240). The study tools were Jean-Louis Sellier 's visual memory test to determine visual memory and ten questions from Gardner Spatial Intelligence Questionnaire were employed to assess spatial intelligence. The tests were performed at the beginning of the semester and its relationship with the academic achievement scores of the anatomy course was examined. Data were analyzed by descriptive statistics, independent t-test, Pearson correlation and multiple linear regression.

RESULTS

Data of 148 medical students and 85 dental students were analyzed. The mean score of visual memory in medical students (17.1±5.3) was significantly higher than dental students (14.3±4.6) (P-value <0.001). But the mean score of spatial intelligence (31.5±5.9) was not significantly different between medical and dental students (31.9±4.9) (P-value=0.56). Pearson correlation coefficient showed that in medical students there was a direct relationship between visual memory score and spatial intelligence score with scores of anatomy courses (P-value<0.05). Moreover, in dental students, there was a direct relationship between the score of anatomical sciences with the score of visual memory (P-value=0.01) and the score of spatial intelligence (P-value=0.003).

CONCLUSION

The results of this study showed that there is a significant relationship between spatial intelligence and visual memory with learning anatomy and planning to enhance these characteristics can be fruitful in students. It is suggested that Visual memory and spatial intelligence should be considered for student admission, especially in the fields of medicine and dentistry.

Social media as a learning tool in anatomy education from the perspective of medical and dental students

The traditional approach to anatomy teaching is still the most common. Recently, there has been a demand for methods that make students more active and open to communication and cooperation, and are well integrated with technology. Our aim in this study was to determine the social media usage characteristics and anatomy learning experiences of medical and dentistry students, and their expectations about learning via social media. A questionnaire was prepared and distributed to faculties of Medicine and Dentistry in 10 different universities in Türkiye via Google forms. The questionnaire was voluntarily answered by 762 students. Frequency, exploratory factor and confirmatory factor analyses were applied to the data acquired, and a structural equation modeling (SEM) approach was used. The results showed that 54.3% of the students spent more than 90 min/day on social media; 96.5% of the participants preferred to follow anatomical content pages on social media (acpSM) administered by an academic. They stated that the instant responses from acpSM's admin had a positive effect on motivation to learning (4.08 ± 0.89, mean ± SD, on 5-point Likert-type scale). The SEM revealed a statistically significant correlation between the students' learning motivation and the sufficiency and suitability of acpSM content (p < 0.010). Thus, medical and dental students are eager to learn anatomy via social media. However, they found acpSM to be insufficient in quality and quantity and wanted future content to be administered by academics. An acpSM optimized for content sufficiency and suitability increased students' learning motivation.

The Future of Morphological Science Education: Learning and Teaching Anatomy in the Wake of the COVID-19 Pandemic

The COVID-19 Pandemic has conveyed an unprecedented worldwide challenge. Although there is much emphasis on caring for patients and communities, the high incidence of SARS-CoV-2 had seriously disturbed education and calls for prompt as well as serious consideration from educators in medical schools. The necessity to teach and prepare prospective medics, as well as clinicians, has certainly not been as intense as it is currently. The global effects of coronavirus disease 2019 may cause a permanent change in the education of future clinicians. The COVID-19 era presented logistical and practical obstacles and fears for the patients' well-being, taking into consideration the fact that students may be potential channels for the spread of the virus when asymptomatic and may get infected while being in training and attending lectures. This paper discusses the present state of morphological science education, depicting the effect of COVID-19 on learning environments, as well as highlights the probable effects of COVID-19 on medical instruction in the future.

A scoping review on the trends of digital anatomy education

Digital technologies are changing the landscape of anatomy education. To reveal the trend of digital anatomy education across medical science disciplines, searches were performed using PubMed, EMBASE, and MEDLINE bibliographic databases for research articles published from January 2010 to June 2021 (inclusive). The search was restricted to publications written in English language and to articles describing teaching tools in undergraduate and postgraduate anatomy and pre-vocational clinical anatomy training courses. Among 156 included studies across six health disciplines, 35% used three-dimensional (3D) digital printing tools, 24.2% augmented reality (AR), 22.3% virtual reality (VR), 11.5% web-based programs, and 4.5% tablet-based apps. There was a clear discipline-dependent preference in the choice and employment of digital anatomy education. AR and VR were the more commonly adopted digital tools for medical and surgical anatomy education, while 3D printing is more broadly used for nursing, allied health and dental health education compared to other digital resources. Digital modalities were predominantly adopted for applied interactive anatomy education and primarily in advanced anatomy curricula such as regional anatomy and neuroanatomy. Moreover, there was a steep increase in VR anatomy combining digital simulation for surgical anatomy training. There is a consistent increase in the adoption of digital modalities in anatomy education across all included health disciplines. AR and VR anatomy incorporating digital simulation will play a more prominent role in medical education of the future. Combining multimodal digital resources that supports blended and interactive learning will further modernize anatomy education, moving medical education further away from its didactic history.

"Preparing them for the profession": An interpretative phenomenological analysis of anatomy educators coping with complexity in the United Kingdom curriculum

Efforts to integrate the basic sciences into the ever-changing curriculum are a trending area of research in health professions education. Low-stakes, high-frequency assessment methods such as the progress test are now widely implemented in the United Kingdom and Northern Ireland as a means of furthering curricular integration toward contemporary goals of competency and professional identity formation. The anatomy educator's experience vis-à-vis these curricular changes is not well understood. This study aimed to explore how anatomy educators make sense of the shifting demands of their role. The interviews were semi-structured, particularly concerned with the phenomenon of teachers adapting to the complexity of their learning environment. The study used interpretative phenomenological analysis (IPA) to focus on the lived experiences of participants coping with the phenomena in question: how do anatomy educators make sense of the learning environment in the United Kingdom? Interviews were transcribed verbatim and interpreted inductively, identifying four key themes: confidence through connectedness, variations in appraisals of curricular integration, managing expectations to perform in paradoxical situations, and the emergence of innovative teaching. Results point to the learning environment as a complex system and highlight the importance of feeling support from and connection to colleagues, enabling individual educators to develop confidence, meet the top-down demands of changing curricula, and experience personal identity development and uncertainty tolerance within their role. This IPA study offers insight into the lived experiences of anatomy educators whose experiential interpretations of a complex and changing curriculum can uniquely inform stakeholders in health professions education.

Teaching Medical Microbiology With a Web-Based Course During the COVID-19 Pandemic: Retrospective Before-and-After Study

BACKGROUND

The COVID-19 pandemic has imposed unprecedented hurdles on health care systems and medical faculties alike. Lecturers of practical courses at medical schools have been confronted with the challenge of transferring knowledge remotely.

OBJECTIVE

We sought to evaluate the effects of a web-based medical microbiology course on learning outcomes and student perceptions.

METHODS

During the summer term of 2020, medical students at Saarland University, Germany, participated in a web-based medical microbiology course. Teaching content comprised clinical scenarios, theoretical knowledge, and instructive videos on microbiological techniques. Test performance, failure rate, and student evaluations, which included open-response items, for the web-based course were compared to those of the on-site course from the summer term of 2019.

RESULTS

Student performance was comparable between both the online-only group and the on-site comparator for both the written exam (n=100 and n=131, respectively; average grade: mean 7.6, SD 1.7 vs mean 7.3, SD 1.8; P=.20) and the oral exam (n=86 and n=139, respectively; average grade: mean 33.6, SD 4.9 vs mean 33.4, SD 4.8; P=.78). Failure rate did not significantly differ between the online-only group and the comparator group (2/84, 2.4% vs 4/120, 3.3%). While lecturer expertise was rated similarly as high by students in both groups (mean 1.47, SD 0.62 vs mean 1.27, SD 0.55; P=.08), students who took the web-based course provided lower scores for interdisciplinarity (mean 1.7, SD 0.73 vs mean 2.53, SD 1.19; P<.001), opportunities for interaction (mean 1.46, SD 0.67 vs mean 2.91, SD 1.03; P<.001), and the extent to which the educational objectives were defined (mean 1.61, SD 0.76 vs mean 3.41, SD 0.95; P<.001). Main critiques formulated within the open-response items concerned organizational deficits.

CONCLUSIONS

Web-based courses in medical microbiology are a feasible teaching option, especially in the setting of a pandemic, leading to similar test performances in comparison to on-site courses. The lack of interaction and the sustainability of acquired manual skills warrant further research.

Virtual Reality and Augmented Reality in Anatomy Education During COVID-19 Pandemic

The pandemic of COVID-19 has radically changed the anatomy education approaches. This happens because medical students, due to the necessity of remote education, didn't have access to cadavers, which was the principal method of dissection training. Circumstances like these encouraged the health care providers to innovate new teaching methods with the help of virtual and augmented reality to outdistance the restrictions. This review aims to examine the pioneer technological and educational tools and their usage in the future. Detailed research was performed via the PubMed database using the following keywords "Virtual Reality (VR), Augmented Reality (AR), Anatomy Education, and COVID-19". No further filters were used. All the existing evidence suggests that the vast majority was negatively affected by the COVID-19 era. Using new technological methods in anatomy training could not effectively replace the absence of the traditionally used teaching methods like dissection, prosection, and lectures by physical presence. Although the new digital anatomy teaching approaches seem to be very promising, it is not clear if they can fully replace the traditional anatomy education methods.

Technology-Enhanced Preclinical Medical Education (Anatomy, Histology and Occasionally, Biochemistry): A Practical Guide

The recent explosion of technological innovations in mobile technology, virtual reality (VR), digital dissection, online learning platform, 3D printing, and augmented reality (AR) has provided new avenues for improving preclinical education, particularly in anatomy and histology education. Anatomy and histology are fundamental components of medical education that teach students the essential knowledge of human body structure and organization. However, these subjects are widely considered to be some of the most difficult disciplines for healthcare students. Students often face challenges in areas such as the complexity and overwhelming volume of knowledge, difficulties in visualizing body structures, navigating and identifying tissue specimens, limited exposure to learning materials, and lack of clinical relevance. The COVID-19 pandemic has further exacerbated the situation by reducing face-to-face teaching opportunities and affecting the availability of body donations for medical education.To overcome these challenges, educators have integrated various educational technologies, such as virtual reality, digital 3D anatomy apps, 3D printing, and AI chatbots, into preclinical education. These technologies have effectively improved students' learning experiences and knowledge retention. However, the integration of technologies into preclinical education requires appropriate pedagogical approaches and logistics to align with educational theories and achieve the intended learning outcomes.The chapter provides practical guidance and examples for integrating technologies into anatomy, histology, and biochemistry preclinical education. The author emphasizes that every technology has its own benefits and limitations and is best suited to specific learning scenarios. Therefore, it is recommended that educators and students should utilize multiple modalities for teaching and learning to achieve the best outcomes. The chapter also acknowledges that cadaver-based anatomy education is essential and proposes that educational technologies can serve as a crucial complement for promoting active learning, problem solving, knowledge application, and enhancing conventional cadaver-based education.

Are extended reality technologies (ERTs) more effective than traditional anatomy education methods?

PURPOSE

Reviews and meta-analyses concerning the effectiveness of extended reality technologies (ERTs) (namely virtual, augmented, and mixed reality-VR, AR, and MR) in anatomy education (AE) have resulted in conflicting outcomes. The current review explores the existing evidence provided by reviews of AE literature regarding the effectiveness of ERTs after their comparison with traditional (either cadaveric or two-dimensional) anatomy teaching modalities and sheds light on the factors associated with the conflicting outcomes.

METHODS

PubMed, SCOPUS, ERIC, and Cochrane databases were searched for review articles with the purpose to investigate the effectiveness of ERTs in AE.

RESULTS

Nine (four systematic with or without meta-analysis and five non-systematic) reviews were included. A lack of robust evidence provided by those reviews was noted, mainly due to a remarkable confusion in the definition of each ERT, along with confusion when authors referred to traditional AE (TAE) methods.

CONCLUSIONS

To clarify to what extent VR, AR, or MR can replace or supplement TAE methods, there is a primary need for addressing issues regarding the definition of each technology and determining which specific TAE methods are used as comparators.

Medical Student Perceptions of Near Peer Teaching within an Histology Course at the University of Sassari, Italy

Near peer teaching (NPT) is becoming recognized as a valuable instrument with advantages for both students and teachers. Despite the recognized benefits, NPT programmes are not usually embedded within university healthcare curricula and, to our knowledge, there have been few studies assessing medical students’ attitudes towards NPT for histology courses. Our study is the first that assess medical students’ perceptions concerning the value of NPT for a course in the human organ histology component of anatomy. A NPT programme was provided for second-year medical students and delivered during laboratory sessions for microscopic anatomy. The NPT tutors were recruited from third-, fourth- or fifth-year medical students. The medical tutees completed a questionnaire to assess their attitudes towards NPT. The initial hypothesis tested was that students preferred to be taught by their professional teachers and not by NPT tutors. A total of 113 students completed the questionnaire (46% response rate). Of these, 70% of respondents rated the support of the NPT tutors as being excellent or good. Furthermore, 60% of respondents agreed that the NPT programme should be introduced officially into the medical curriculum. The findings are not consistent with our initial hypothesis, and suggest that NPT could be a valuable instrument for the understanding of histological concepts.

Teaching gross anatomy during the Covid-19 pandemic: Effects on medical students' gain of knowledge, confidence levels and pandemic-related concerns

For medical students the dissection course is the preferred method to learn gross anatomy. However, the added value of active cadaver dissection on knowledge gain in multimodal curricula offering a diversity of e-learning resources is unknown. The Covid-19-related lockdown forced educators to replace the dissection course by e-learning resources. At the end of the summer term 2020 loosening of pandemic-related regulations allowed offering a compact, voluntary active dissection course of the head-neck region to first-year medical students at Hannover Medical School. A study was conducted comparing a dissection group (G1, n = 115) and a non-dissection group (G2, n = 23). Knowledge gain and confidence level were measured with a multiple-choice (MC-)test. The use of e-learning resources was recorded. A questionnaire measured motivation, interest and level of concern regarding Covid-19 and anatomy teaching. No differences between groups were found regarding motivation and interest in anatomy of the head-neck region. G2, however, had significantly higher concerns regarding the Covid-19 pandemic than G1. Neither before nor after the educational intervention, differences in the scores of the MC-test were found. However, after the course G1 answered more MC-questions with highest confidence level than G2 (6.7 ± 6.0 vs. 3.6 ± 4.6, p < 0.05) and demonstrated by trend an increased improvement in the scores of image-based questions (30.8 ± 18.2 % vs. 17.1 ± 14.8 %, p = 0.06). In general, frequent users of online quizzes, a part of the e-learning resources, scored significantly better in the knowledge test. Active dissection improves self-assurance to identify anatomical structures and should be re-implemented in multimodal, blended-learning-based anatomical curricula in the post-pandemic era.

Evaluation of the effectiveness of online education in anatomy for medical students during the COVID-19 pandemic

Background

In the field of medicine, anatomy is considered one of the most important subjects to be studied in college, even for clinicians. Learning from cadaveric specimens is considered an important part of the medical experience. The current study consisted of a questionnaire given to Year 1 and Year 2 medical students. This study was performed to assess using a questionnaire whether students were capable of continuing studying Anatomy during the COVID-19 period.

Methods

The study consisted of 102 students in Years 1 and 2 of the Faculty of Medicine of Alexandria University in Egypt. It included Year 1 Students (mean age 18.6 ± 1.1 years old; 21 males and 36 females), and Year 2 Students (mean age 20.4 ± 1.0 years old; 22 males and 23 females).

The survey consisted of three sections. The first section consisted of four questions on the demographic data of the participating students. The second section consisted of 10 questions concerning their satisfaction with the tutorials and presented by the Department of Anatomy. Answers to the questionnaire were in the form of a Likert scale (with 1 = strongly disagree to 5 = strongly agree).

Results

The students disagreed with the fact that they found difficulty in time management, represented by a mean score of 2.23 ± 1.14. That is to say, the students were capable of managing their time well. Here also, the difference between Year 1 and Year 2 students was significant (p = 0.028), which is an indicator that Year 2 students found more difficulty in time management. Most students agreed (mean score of 3.48 ± 1.07) that they were able to handle online learning and the transition between the systems was acceptable. Students were also convinced and agreed that the methods used by the college limited the spread of COVID-19 (mean score of 3.81 ± 1.04). Allowing assignments and projects increased the interaction between the students and the staff members.

Conclusions

Education must continue during the COVID-19 period, based on their responses and opinions in the questionnaire. Online learning proved to be effective in teaching medical students during the COVID-19 pandemic.

Technology Behavior Model—Impact of Extended Reality on Patient Surgery

Smart surgery is a new way to utilize smart devices to change existing surgeries. Smart glasses can enhance the surgical procedure so that the patient can understand the procedure more intuitively. Surgery is for patients, and patient acceptance of extended reality surgery is the purpose of this study. This study uses the technology behavior model, which is more in line with the user’s assessment of the acceptance behavior of the new technology. A triangulated research approach was used, which applies to this study for a specific patient population. Primary data were collected from hospitals through questionnaires and were statistically analyzed by CB&PLS-SEM multimodel using SmartPLS software. It was concluded that patients were influenced by operational emotional factors in undergoing extended reality surgery. The study provides a basis for future research related to the practical application of smart surgery from the patient’s perspective in viewing and accepting surgery.