Three-Dimensional Virtual Anatomy as a New Approach for Medical Student's Learning

Fostering engagement in virtual anatomy learning for healthcare students

BACKGROUND

The use of virtual learning platforms is on the rise internationally, however, successful integration into existing curricula is a complex undertaking fraught with unintended consequences. Looking beyond medical and pedagogic literature can provide insight into factors affecting the user experience. The technology acceptance model, widely used in software evaluation, can be used to identify barriers and enablers of engagement with virtual learning platforms. Here, the technology acceptance model was used to scaffold the exploration of the factors that influenced students' perceptions of the virtual anatomy platform, Anatomage and how these shaped their intention to use it.

METHODS

Focus groups identified factors influencing students use of the Anatomage tables. Interventions were rolled out to address these findings, then further focus groups and the technology acceptance model identified how factors including self-efficacy, enjoyment, and social norms influenced students' intention to use the Anatomage table in the future.

RESULTS

Students raised significant concerns about understanding how to use the Anatomage table. Moreover, students who considered themselves to be poor at using technology perceived the Anatomage table as more complicated to use. The subjective norm of the group significantly altered the perceived ease of use and usefulness of the Anatomage. However, enjoyment had the greatest impact in influencing both perceived usefulness and perceived ease of use. Indicating that enjoyment is the largest contributing factor in altering technology engagement in healthcare cohorts and has the biggest potential to be manipulated to promote engagement.

CONCLUSIONS

Focus groups used in tandem with the technology acceptance model provide an effective way to understand student perceptions around technology used in the healthcare curricula. This research determined interventions that promote student engagement with virtual learning platforms, which are important in supporting all healthcare programmes that incorporate technology enhanced learning.

Virtual Dissection: an Educational Technology to Enrich Medical Students' Learning Environment in Gastrointestinal Anatomy Course

Background

Virtual dissection provides a digital experience of medical images to visualize anatomy on touchscreen tables. This study aimed to integrate the virtual dissection table (VDT) into the gastrointestinal anatomy course and assess medical students' intended learning outcomes and satisfaction with this educational technology.

Methods

This quasi-experimental study enrolled second-year undergraduate medical students who studied anatomical sciences in the autumn semester of 2021-2022 at a single medical school. In the intervention and control groups, the participants were randomized to study anatomy by VDT or topographical anatomy textbooks. The knowledge tests evaluated the students' learning outcomes of gastrointestinal anatomy, and following the course, students completed a satisfaction survey.

Results

The findings indicated that a significant gain occurred, and instructional intervention during which the learning environment was enriched with virtual dissection could enhance the students' learning (F = 13.33, df = 2, P < 0.01, partial η2 = 0.20) and satisfaction (T = 6.10, df = 54, P < 0.01, Cohen's d = 1.63, CI95% = 1.02-2.23).

Conclusions

This study demonstrates the potential for virtual dissection to augment anatomical science education. Further research is required to consider the contributing features and apply this educational technology to enhance students' anatomy learning.

Supplementary Information

The online version contains supplementary material available at 10.1007/s40670-023-01867-z.

Utility of the Anatomage Virtual Dissection Table in Creating Clinical Anatomy and Radiology Learning Modules

Purpose

During the COVID-19 pandemic, teaching has required online-learning modalities to facilitate easily accessible yet high-quality education. However, since the nature of anatomy requires hands-on experience in laboratories with cadavers, teaching anatomy in an online setting has proven especially difficult. This matter may be resolved with the Anatomage Table, an advanced anatomy visualization tool, which several studies have suggested can augment learning experiences for students in anatomy courses. Our objective was to provide accessible online modules, through utilization of the Anatomage Table, for medical students to facilitate their learning and enhance online learning experience.

Materials and Methods

Ten modules were designed, consisting of a presentation, a pre- and post-self-assessment, as well as anatomical images and radiographs taken from Anatomage Table. The modules were based on a single organ system, and a clinical case pertaining to that organ system was presented. Weill Cornell Medicine-Qatar (WCM-Q) second-year medical students contributed 102 responses in total throughout the 10 modules. Using a paired t-test, the study compared the students' pre- and post-assessment scores to determine how beneficial the modules were.

Results

A significant difference in scores on the pre- and post-assessments was found for all 10 modules using a paired t-test. At the end of the modules, the students completed a feedback survey to assess the quality and convenience. Most of the students agreed or strongly agreed that the modules were beneficial to their online anatomy learning and wanted to see similar anatomical modules in the future.

Conclusion

The Anatomage Table is an innovative virtual resource that can significantly contribute to a more engaging and productive experience for medical students.

Perceptions and Attitudes of Jordanian Medical Students on Using 3D Interactive Anatomy Dissection in Teaching and Learning Anatomy

BACKGROUND AND AIMS

This study evaluates the use of virtual anatomy dissection (Anatomage Table) in teaching anatomy for Jordanian medical students. The study also highlights any gender differences in students' perception on this method of teaching anatomy.

METHODS

This is a cross-sectional questionnaire-based study that was carried out on medical students enrolled in Al-Balqa Applied University, a Jordanian public university. A group of expert anatomists designed a questionnaire that investigates the students' perceptions and attitudes toward using virtual anatomy dissection. The questionnaire also investigated student's opinions and expectations on the impact of using this method on the academic achievement of students.

RESULTS

The findings of the study showed that most students agreed that Anatomage Table helped them better understand (64.3%) and memorize (64%) anatomy lectures. In addition, most students were interested in using this learning method in lab groups (72.3%). However, the didactic approach that combined anatomical models and the Anatomage Table was preferred over the unilateral approach that included only the Anatomage Table (80.5% vs 30.2%, p<0.001, r=0.9). Of note, there was a statistically significant difference between males and females in their preference for Anatomage Table (p<0.001), and in their perceptions on the impact of Anatomage Table on understanding of lectures (p<0.001) and memorization of anatomical structures (p=0.004).

CONCLUSION

The Anatomage Table is a powerful teaching and learning method in undergraduate medical education. Its application to Al-Balqa Applied University has proven to be effective so far. It can be used to overcome the problems facing anatomical education in the college of medicine in Al-Balqa Applied University and perhaps other universities in Jordan, but this needs better cooperation between universities and stakeholders to provide adequate funding for this method.

The Anatomage Table: A Promising Alternative in Anatomy Education

Anatomy is one of medical and nursing education's most prominent and crucial keynotes. For ages, conventional lectures and the analysis of actual human corpses were employed as predominant teaching techniques. However, the sphere of healthcare pedagogy has been greatly altered by the developing passion for technology over the past few years. Anatomage offers a life-size digital representation of the human body, allowing the visualization, manipulation, and virtual dissection of complex anatomical structures, using detailed 3D (three-dimensional) models. Academic institutions utilize Anatomage as a means to enhance and contemporize the acquisition of anatomy knowledge. This systematic review aims to present the educational role of Anatomage in anatomy and whether it can replace the use of cadaveric material in medical education entirely in the future.  A detailed search on PubMed, SCOPUS, Wiley Online Library, and Google Scholar databases was performed. The criteria for the selection were the English language and the year of publication between 2018 and 2023. We rejected publications that were irrelevant to the topic. Before applying the filters, we found 198 publications, from which 24 were finally chosen for the purpose of this review.  The results of this systematic review indicate that most students agree on the beneficial role of Anatomage in the thorough comprehension of anatomical knowledge, and they prefer it over traditional learning methods, such as the use of cadaveric material. Anatomage not only offers a deeper insight into the relations between inner formations, since it is a particularly easy-to-use and pleasant teaching tool, but also contributes to the improvement of learning outcomes in the classroom, which is proved by higher grades in the anatomy course. However, it can be an effective teaching method if it is used in addition to the classic method of cadaver training, rather than being the only educational practice.  Integrating the Anatomage Table (AT) into undergraduate courses is paramount to the comprehensive learning and application of human anatomy in students' future health careers. Learners who have utilized the table note it to be a beneficial and effective tool in preparing them to enter into the healthcare profession.

Role of Living Anatomy in Medical Education: A Narrative Review

Introduction

There has been a significant change noticed in the way in how anatomy is taught and learned in last two decades. The use of teaching approaches such as body painting, peer physical examination, medical imaging, and virtual anatomy software in the teaching and learning of living anatomy was made possible by advancements in medical technology. This study focuses on a review of the historical context and contemporary developments in teaching and learning of live and surface anatomy with a special emphasis on its pedagogical elements, some opinions of medical educationists, and undergraduates.

Conclusions

It is suggested that living anatomy be included as a core subject in the curriculum. Learning about living anatomy will be improved in an integrated and pertinent framework with the inclusion and execution of teaching and learning modalities such as body painting, peer physical examination, medical imaging, and virtual anatomy software.

Protocol Development for Digisection: Making a Case for Standardizing Educational Technology Use for Digital Dissection and Anatomical Studies

The changes that have characterized advancements in anatomical sciences and medical education have significantly influenced pedagogies and the mode of delivery of teaching and training in the context of medical education. Another reality is the impact of educational technology (EdTech) penetration and integration into medical sciences and education. These events have undoubtedly influenced certain traditional practices and pedagogies including dissection. For example, EdTech and innovations have introduced virtual human images and three-dimensional (3D) human body representations for the purposes of teaching and dissection. Another instance includes the fact that the old dissection guides for gross anatomy, which follow the traditional regional anatomy approach, are often challenging to adapt to the relatively modern medical school curriculum that has embraced the integration philosophy. It is apparent that one practical and realistic way to provide an adapted and effective guide for anatomical dissections under various curricular philosophies and contexts would be to develop de novo protocols or adapt existing ones. Protocol development would be a vital component of the modern anatomist toolkit. This article presents the basic considerations and practical approach, including underpinning principles, to developing virtual dissection protocols using a digital 3D dissection facility, the Anatomage table (Anatomage Inc., California, United States of America), as a case study.

Do virtual dissection tables add benefit to cadaver-based anatomy education? An evaluation

PURPOSE

The anatomy education literature suggests blended-learning approaches as more effective. We performed a literature review to answer the question if virtual dissection tables can play a significant role as supplements to traditional cadaver-based anatomy education methods.

METHODS

PubMed, SCOPUS, ERIC and Cochrane databases were searched for articles with purpose to explore the outcomes of the use of virtual dissection tables in conjunction with cadaver-based anatomy education.

RESULTS

Six articles were included. Three articles were comparative and comprised evaluation of participants' anatomy examinations results. Three articles were non-comparative and comprised only evaluation of participants' opinions about the educational intervention. In all studies, the participants expressed satisfaction about the educational value of this intervention, while the data about anatomy examinations' results suggest that virtual dissection tables may also enhance students' academic performance, when they are used in conjunction with cadavers.

CONCLUSION

Virtual dissection tables seem to do have a role in modern blended-learning anatomy curricula and could essentially supplement the educational power of cadaver-based methods. Our findings may stimulate further implementation of virtual dissection tables as supplementary tools to cadaver-based anatomy education.

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.

Digital Transformation Will Change Medical Education and Rehabilitation in Spine Surgery

The concept of minimally invasive spine therapy (MIST) has been proposed as a treatment strategy to reduce the need for overall patient care, including not only minimally invasive spine surgery (MISS) but also conservative treatment and rehabilitation. To maximize the effectiveness of patient care in spine surgery, the educational needs of medical students, residents, and patient rehabilitation can be enhanced by digital transformation (DX), including virtual reality (VR), augmented reality (AR), mixed reality (MR), and extended reality (XR), three-dimensional (3D) medical images and holograms; wearable sensors, high-performance video cameras, fifth-generation wireless system (5G) and wireless fidelity (Wi-Fi), artificial intelligence, and head-mounted displays (HMDs). Furthermore, to comply with the guidelines for social distancing due to the unexpected COVID-19 pandemic, the use of DX to maintain healthcare and education is becoming more innovative than ever before. In medical education, with the evolution of science and technology, it has become mandatory to provide a highly interactive educational environment and experience using DX technology for residents and medical students, known as digital natives. This study describes an approach to pre- and intraoperative medical education and postoperative rehabilitation using DX in the field of spine surgery that was implemented during the COVID-19 pandemic and will be utilized thereafter.