Effectiveness of Virtual Reality and Interactive Simulators on Dental Education Outcomes: Systematic Review

• Abstract
• Introduction
• Methods
• Protocol and Eligibility Criteria
• Information Sources
• Study Selection
• Data Collection
• Results
• Studies Included
• Description of the Study Characteristics
• Restorative Dentistry
• Endodontics
• Oral and Maxillofacial Surgery
• Prosthodontics
• Implantology
• Oral and Maxillofacial Radiology
• Periodontology
• Pediatric Dentistry
• Orthodontics
• Miscellaneous Dental Skills
• Discussion
• Limitations
• Conclusion
• References

Abstract

In recent years, virtual reality and interactive digital simulations have been used in dental education to train dental students before interacting with real patients. Scientific evidence presented the application of virtual technology in dental education and some recent publications suggested that virtual and haptic technologies may have positive effects on dental education outcomes. The aim of this systematic review was to determine whether virtual technologies have positive effects on dental education outcomes and to explore the attitudes of dental students and educators toward these technologies. A thorough search was conducted in PubMed, Scopus, MEDLINE (via EBSCO), The Cochrane Library (via Wiley), Web of Science Core Collection (via Thomson Reuters), and Dentistry and Oral Science source (via EBSCO) using the keywords (student, dental) AND (education, dental) AND (virtual reality) OR (augmented reality) OR (haptics) OR (simulation) AND (dentistry) OR (dental medicine). The quality of the reported information was assessed following the Preferred Reporting Items for Systematic Review and Meta-Analysis (PRISMA) statement for systematic reviews. A total of 73 publications were considered for this review. Fifty-two of the selected studies showed significant improvement in educational outcomes and virtual technologies were positively perceived by all the participants. Within the limitations of this review, virtual technology appears to improve education outcomes in dental students. Further studies with larger samples and longer term clinical trials are needed to substantiate this potential positive impact of various virtual technologies on dental education outcomes.

Introduction

In recent years, virtual reality (VR) simulations have been employed in dental education as an adjunctive to the traditional skill training curriculum to train dental students before interacting with actual patients.[1] [2] Dental education differs from any other form of medical education as it is a combination of theory, laboratory, and clinical practice. The challenge in dental education arises from the fact that theoretical knowledge acquisition requires spatial imagination and the patient-centered training on traditional mannequin simulation does not resemble realistic clinical situations.[3] Preclinical and clinical training is of paramount importance for developing fine motor skills to prepare dental students to engage in the dental profession. Many of the required dental education competency skills are challenging to acquire, and mandates repeated training and long practice.[4] Since the breakthrough of the novel coronavirus SARS-Co-V-2 (severe acute respiratory syndrome coronavirus 2) in late 2019,[5] all essential activities were affected, calling for social distancing, and the traditional dental teaching models of one-on-one pedagogical design had to be partially replaced by digital or virtual setups to avoid the gathering of the youth in closed spaces.

VR is gaining acknowledgment as a valuable tool for training dental students, and its use by dental schools is rising worldwide.[6] VR is defined as a computer-generated medical simulation of a three-dimensional (3D) image or environment that uses software to create an immersive computer-generated environment. Users put on a head-mounted display that places them inside an experience, where they can engage with the setting and virtual characters in a way that feels real. VR could be beneficial in dental education, permitting a patient noncontact training environment.[1] [2]

Augmented reality (AR) is a superimposition of computer-generated graphics over a real-life scene. It differs from VR, which does not demonstrate natural conditions. AR refers to a form of technology that integrates both real and virtual elements in a combined experience and allows learners to visualize complex spatial relationships, abstract concepts, and experience phenomena that might have been impossible in the real world, especially in surgical procedures coaching.[7] [8] Immersive virtual reality (IVR) is one form of AR where the user interacts with a digital 3D environment recreated through 360 degrees actual records.[9]

Haptic technology (HT) is a more recent simulation that involves tactile sensation while interacting with computer-generated objects. Haptics means the sense of touch and consists of the science of incorporating the interaction with the external environment through contact.[2] Implementing these technologies in dental education motivated designers to create virtual teeth with and without pathology, multilayered and featured with different mechanical hardness for enhanced reality.[10] [11]

The applications of VR in dental education attracted the attention of researchers even in the early experimental stages.[7] It was suggested that it could enhance dental education compared with traditional teaching,[1] especially in the training of restorative dentistry,[12] [13] and dental surgery,[14] [15] although it may expand to include endodontics and orthodontics.[16] [17] [18] VR enabled the delivery of distant online lectures through 3D VR workplace. The flexibility of the technology allowed the attendees’ active contribution and facilitated 3D understanding of surgery and related anatomy, despite the limitation of technical issues.[19] However, the results of VR effectiveness in dental education outcomes are controversial. Thus, this systematic review aimed to evaluate the effectiveness of VR simulations on dental education outcomes. The assessed results of VR interventions were knowledge, clinical skills, attitude, and satisfaction of both learners and educators.

Methods

Protocol and Eligibility Criteria

This systematic review was conducted according to the Preferred Reporting Items for Systematic Review and Meta-Analysis (PRISMA) guidelines.[20] A modified PICOS search was defined, and studies that fulfilled the following criteria were selected:

1. Population (P): Undergraduate and postgraduate dental learners enrolled in any dental-related education or training program were included in the review.

2. Intervention (I): Virtual simulation teaching and assessment methods including but not limited to VR, AR, and HT.

3. Primary outcomes (O): Include clinical competencies measured pre or post intervention represented in learners’ knowledge and manual skills. Secondary outcomes included students’ and educators’ perceptions of VR designs.

4. Study design (S): the review applied no limits for the study design.

5. Comparison (C): was not a mandatory item to include a study in this review.

Information Sources

A systematic electronic search was performed limited to English language articles published between January 2010 to the end of March 2021. Studies were identified by searching the following electronic databases for relevant studies: PubMed, Scopus, MEDLINE (via EBSCO), The Cochrane Library (via Wiley), Web of Science Core Collection (via Thomson Reuters), and Dentistry and Oral Science source (via EBSCO).

The following search terms were used for identification of eligible studies: (student, dental) AND (education, dental) AND (VR) OR (AR) OR (haptics) OR (simulation) AND (dentistry) OR (dental medicine). Keywords were adjusted for use with each of the databases mentioned earlier. Further electronic search of the relevant articles in the Journal of Dental Education and the European Journal of Dental Education was performed while running our electronic search. The bibliographies of the revealed full texts, were manually searched for additonal studies.

Study Selection

The search results were combined in a single Mendeley library (Mendeley Desktop v1.19.6) and duplicates were excluded. Two authors independently screened titles, abstracts to identify potentially eligible studies. Exclusion criteria included preliminary reports, reports without an underlying study design, and studies describing the software or hardware of the virtual technology. One co-author retrieved full-text versions of the selected studies. Selected publications were independently reviewed by two investigators.

Data Collection

Customized forms following the guidelines of the Cochrane Consumers and Communication Review Group template for review authors,[21] were used to record the following data from the selected studies:

• Characteristics of the study: study design, research country, and time of intervention (before-after).

• Characteristics of the study participants: number of participants, stage of education (under or postgraduate), and year of study.

• Virtual intervention applied: dental specialty where simulation was used, type of the system, and the source of virtual simulations: whether access to virtual simulation was from home or at academic laboratories.

• The outcome investigated; subjective or objective assessment, and the tools used to measure the output.

• Results of the selected studies.

Results

Studies Included

The study selection process for inclusion in this review is summarized in [Fig. 1] (diagram flow). The database search strategy identified 498 potentially eligible references. Twelve additional articles were included after review of references. Duplicates were excluded. After screening titles, abstracts, 437 articles were excluded applying the exclusion criteria. Eventually 73 studies were included in the review that included 5,275 participants.

The retrieved studies were categorized according to the field of dental education in which VR was applied. [Fig. 2] shows the percentile representation of each dental specialty in the selected studies.

Description of the Study Characteristics

Restorative Dentistry

Twenty-three of the selected studies applied VR in restorative dentistry with total included participants, n = 2,201, in which 62.1%, n = 1,367 were first year dental students. The detailed characteristics of the included studies are shown in [Table 1]. HT was the most used in 18 of the selected studies,[12] [22] [23] [24] [25] [26] [27] [28] [29] [30] [31] [32] [33] [34] [35] [36] [37] [38] VR simulator in three studies[39] [40] [41] and AR,[13] and interactive video games,[42] one study each. Access to all these technologies was through academic laboratories except in one study.[13] In the selected studies, students’ manual skills was the most common tested outcome represented in cavity preparations in 52.17%, n = 12,[13] [24] [25] [28] [29] [30] [33] [34] [35] [38] [39] [41] or geometric figures 34.78%, n = 8.[12] [22] [23] [26] [27] [31] [32] [36] Other manual skills tested were dentin etching and resin bonding,[42] and zinc phosphate cement application,[40] one study each. Four studies assessed VR on theoretical knowledge.[13] [37] [40] [42] Results showed significant difference in 14 of the selected studies in manual clinical skills[12] [13] [23] [27] [29] [30] [31] [34] [35] [36] [38] [39] [40] [41] and two studies in theoretical knowledge.[37] [40]

Endodontics

Six of the selected studies applied VR in endodontic with total included participants, n = 189. Characteristics of the selected studies are shown in [Table 2]. HT was applied for access opening in three studies,[43] [44] [45] and surgical apicectomy in two studies.[14] [15] VR simulation was used in one study to teach root canal anatomy.[46] Four studies showed significant better results of the virtual technology.[14] [43] [44] [46] Students highly appreciated virtual training in one study,[15] although suggested modifications in spatial registration precision, FFB of different tissues, and more realistic models in another study.[45]

Oral and Maxillofacial Surgery

Nine of the selected studies applied VR technologies in oral and maxillofacial surgery education with total included participants, n = 730. Characteristics of the selected studies are shown in [Table 3]. Virtual patient (VP) simulation was applied in four studies,[47] [48] [49] [50] AR in three studies,[51] [52] [53] and IVR in two studies.[54] [55] Results showed significant differences in all the selected studies except one study.[53] Participants positively appreciated the value of the VR in education, and the test groups reported significantly higher self-confidence.

Prosthodontics

Thirteen of the selected studies applied VR in prosthodontics with total included participants, n = 815. Characteristics of the selected studies are shown in [Table 4].

All studies applied VR in fixed prosthodontics training and evaluation, except two studies: one in preclinical removable partial denture prosthodontics course,[56] and the second in teaching occlusion.[57] Manual skills of tooth preparation was evaluated in nine of the selected studies,[58] [59] [60] [61] [62] [63] [64] [65] [66] [67] acquired knowledge in one study,[57] and students’ perception in three studies.[3] [56] [59] Nine studies reported significant statistical differences of the VR scores.[57] [58] [60] [61] [62] [63] [64] [65] [66] [67]

Implantology

Five of the selected studies applied dental implant education with total included participants, n = 351. Characteristics of the selected studies are shown in [Table 5]. Implant placement manual skills were assessed in four studies,[68] [69] [70] [71] and theoretical knowledge in two studies.[70] [72] Results of all the selected studies showed significant improvement of implant education outcomes in both clinical skills and theoretical knowledge.

Oral and Maxillofacial Radiology

Two studies reported the application of VR in dental radiology education with total included participants, n = 84. Characteristics of the selected studies are shown in [Table 6]. Both studies reported significant improvement of students’ skill to interpret spatial information in radiographs and acquisition of theoretical knowledge, although OSCE scores were insignificantly different.[73] [74]

Periodontology

Two studies considered HT in periodontology with total included participants, n = 55. Characteristics of the selected studies are shown in [Table 7]. HT features were evaluated as high realistic in periodontal tasks,[75] and significantly improved pocket probing scores.[76]

Pediatric Dentistry

Four studies applied VR in pediatric dentistry with total included participants, n = 295. Characteristics of the selected studies are shown in [Table 8]. Pediatric VP significantly improved behavior and communication management,[77] and AR significantly improved infiltrative anesthesia administration time.[78] Students highly perceived HT in the training on pediatric clinical tasks,[79] and VR superimposing 3D holograms in local anesthesia administration.[80]

Orthodontics

One study considered VR in orthodontics education. The study applied Scenario Based Learning Interactive software (SBLi) on orthodontics postgraduates, n = 9. Participants reported a high acceptance rate of the package, greater confidence applying the clinical skills covered in the modules, and reduced contact time.[81]

Miscellaneous Dental Skills

Eight studies applied virtual strategies in teaching miscellaneous dental skills; critical thinking,[82] professionalism,[83] scientific writing,[84] knowledge of home dental practice,[85] head and neck anatomy,[86] dental morphology,[87] dental diagnosis,[88] and social aspects of dental care delivery.[89] Total included participants were n = 543. Characteristics of the selected studies are shown in [Table 9].

Discussion

The application of VR in dental education has evolved increasingly, and there is significant scientific evidence that describes different virtual setups in different dental educational modules. However, the actual significance of VR simulation on dental education outcomes is not entirely clear. Earlier, VR may have been considered luxurious or optional, nevertheless in the shadow of the global COVID-19 (coronavirus disease 2019) pandemic, dental students need to proceed with their curriculum without any setbacks of the physical presence. VR may provide an opportunity for dental students to build and retain theoretical and clinical dental expertise remotely.

This systematic review showed that VR significantly enhanced the acquisition of dental manual skills even in short periods of training and, to a lesser extent, retention of theoretical knowledge. Despite the fact that few studies reported longer periods of follow-up and reported insignificant differences between virtual and traditional groups.[39] [48] [49] [74]

The diversity in students’ learning styles and motivation is the crucial challenge which course designers face. The introduction of virtual simulators in the dental curriculum and the utilization of its data to stratify dental students and predict their clinical performance would provide the opportunity to tailor the learning process to meet individual diversity in students’ expertise and allow students to work at their own pace. In this context, the dental curriculum could provide an education that leads to the optimal performance of each student.[26]

Based on the results of this review, five broad, interrelated areas of significance arose; first, the versatility of VR applications and the increased application in some dental disciplines over others; second, HT and its wide use in dental education; third, the development of virtual dental patients to enhance dental education; fourth, the value of digital real-time feedback; and fifth, the access of students to the virtual technology.

First, VR applied in dental education showed a wide range of devices and applied technologies ranging from VR simulation with or without immersive environment, haptic simulators with or without force feedback, AR devices, real-time digital mapping and evaluation, virtual mobile platforms, video games, and other forms of virtual packages. The diversity of the individualized detailed features reflects the fact that there are no well-known educational standards for dental simulators or associated exercises. Additionally, it is doubtful how the variable reliability of the simulator systems may affect dental education outcomes.[6] Taking into consideration the complexity of the required dental training to reach a high degree of clinical competence, most of the studies included in this review applied VR in restorative dentistry, prosthodontics, and oral and maxillofacial surgery. In contrast, few studies represented pediatric dentistry, dental radiology, periodontology, and orthodontics. Restorative dental tasks might offer the feasibility of customization of the required assignments, whereas other dental disciplines may require higher customization and knowledge to fulfill specific field’s requirements.[90]

Second, this review showed that HT was the most used technology, especially in tasks that require drilling and tooth preparations, which agree with Towers et al.[6] HT offers an additional dimension to VR through the sense of touch and force feedback (FFB) of the different tooth-layered structure and bone. Thus, HT proved efficient in training junior dental students the hand-eye coordination and spatial reasoning skills. It also helped students improve the preparation accuracy, shortened the preparation time in the very early stages of training, and augmented a conservative preparation approach.[15] [22] [37] [68] However, due to the unique character of dental procedures, FFB should be improved and included as an integral feature in any educational dental simulator to enhance the perception of the tooth structure and different layers of bone. Training with FFB provides a sense of realism and allows the learner to obtain the feel of an invasive procedure in a virtual learning environment.[23] [27]

Third, VP showed wide applications in dental education and had a significant positive impact on manual skills and theoretical knowledge acquisition. VP reduced anxiety associated with real patient’s management while executing a treatment plan, exposed students to an interactive learning experience, enriched self-assessed competence, and augmented confidence to deal with actual patients. As simulators offer flexibility in terms of time, this allowed the students to repeat the procedure until they demonstrate acceptable skill levels without violating real patients and eliminating the need for prolonged direct contact.[47] [48] [49] [53] [77] Still, VP for dental training requires further development to simulate the patient’s oral environment of gingival tissues, saliva, tongue movements, and reflexes as gagging, cough, and head movements. Accordingly, it would aid in teaching emergency management in the dental setting.[75]

Fourth, VR applications with real-time dental training and evaluation systems were very beneficial in acquiring motor skills in preclinical settings. It allowed instantaneous feedback of the students’ performance, enhanced students’ self-assessment, and correction and eliminated the subjectivity of evaluation.[59] [64] [65] Nevertheless, dental students indicated that the simulating devices’ instructions and feedback should be adjunctive to but not a replacement to the faculty feedback. Faculty should be attentive to their responsibility in teaching young dentists, treating patients with individual needs, requiring empathy and informed consent for any treatment decision. The faculty’s role-model function is essential when supervising students during patient treatment in clinical practices, complex problem solving, in-depth conceptual coverage, and peer interaction. Continuous training with faculty supervision and feedback is still an anticipated key to good dental education.

Fifth, most of the studies applied VR through academic laboratories, a fact that should be reconsidered, and alternative mobile platforms should be developed. To benefit from the technology, the student must be physically present on the academic campus. This situation limits to a great extent the range of getting most of the benefit of the virtual technology due to the condensed academic timetables and the increased training times required. Meanwhile, curriculum designers should notice that virtual applications on personal computers and mobiles might leave the whole education process in the student’s hands, for whom some can organize their time accordingly, while others cannot. Thus, supervisors and teachers must monitor the learning process since a lack of motivation in some students would downgrade the technology’s benefit.[13] In this context, tutors should operate continuous assessment in the form of pop-up quizzes, group discussions, and scheduled assignments or presentations, which would eventually lead to a blended form of learning, highlighting the teacher’s role.[48]

Based on the results of this review, it is recommended that low-cost VR hard and software be made readily available to create safe and cost-effective interactive educational training, allowing learners and trainees instantaneous engagement through their personal computers or mobiles. It is advised to clarify learning contents and the extent to which conventional workflows should be taught, aside from the virtual content. One form of a teaching strategy that should be utilized on a wider scale is educational video games. This form of educational material elevated students’ enthusiasm for learning and made learning an enjoyable process.[42] [84] Young generations are more prominent in adapting to new technologies and increasingly familiarized with video games, encouraging further development and improvements in this field to introduce education with more fun.

Limitations

Our study has several limitations. The retrospective nature of our review, incorporating data from published studies and not on individual patients, limits the availability of information on some issues as long-term follow-up of the students and the influence of VR on clinical practices. The search process revealed heterogenous studies addressing the systematic review’s aim, and while meta-analysis was not feasible, we conducted a descriptive approach for identifying the effective outcome of virtual applications. Custom-made software was only used by authors who first described them, which is a significant flaw and could represent a conflict of interest in validating a new proposed system. Also, there was a lack of randomized clinical trials with a proper sample size calculation and other efforts to avoid major bias.

Conclusion

Advanced simulation technology improved the quality of dental education outcomes. It offered applications in different dental disciplines and various clinical procedures. HT enhanced manual skills and perceived self-confidence within few clinical sessions. The most remarkable improvement was the cavity walls convergence, pulpal floor, extension of class I, cavity outline, fewer pulpal exposure, and faster preparation. Students performed better in 3D than 2D vision, with FFB than without, and with a combined instructor and device feedback than with instructor or device feedback alone. Quality of crown preparation and implant placement improved over time after using VR with or without instructor’s feedback. AR reinforced orthognathic surgical training, virtual apicectomies, and local anesthesia administration. Application of VR improved acquisition of theoretical knowledge to a lesser extent. The role of the teacher and verbal instructions cannot be ruled out.

Conflict of Interest

None declared.

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Article published online:
24 August 2021

© 2021. The Author(s). This is an open access article published by Thieme under the terms of the Creative Commons Attribution License, permitting unrestricted use, distribution, and reproduction so long as the original work is properly cited. (https://creativecommons.org/licenses/by/4.0/).

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  CrossrefPubMedGoogle Scholar
• 65 Liu L, Zhou R, Yuan S. et al. Simulation training for ceramic crown preparation in the dental setting using a virtual educational system. Eur J Dent Educ 2020; 24 (02) 199-206
  CrossrefPubMedGoogle Scholar
• 66 Tang L, Cao Y, Liu Z. et al. Improving the quality of preclinical simulation training for dental students using a new digital real-time evaluation system. Eur J Dent Educ 2021; 25 (01) 100-107
  CrossrefPubMedGoogle Scholar
• 67 Al-Saud LM, Mushtaq F, Mann RP. et al. Early assessment with a virtual reality haptic simulator predicts performance in clinical practice. BMJ Simul Technol Enhanc Learn 2020; 6 (05) 274-278
  CrossrefPubMedGoogle Scholar
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  CrossrefPubMedGoogle Scholar
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  CrossrefPubMedGoogle Scholar
• 71 Zorzal ER, Paulo SF, Rodrigues P, Mendes JJ, Lopes DS. An immersive educational tool for dental implant placement: a study on user acceptance. Int J Med Inform 2021; 146: 104342
  CrossrefPubMedGoogle Scholar
• 72 Qi S, Yan Y, Li R, Hu J. The impact of active versus passive use of 3D technology: a study of dental students at Wuhan University, China. J Dent Educ 2013; 77 (11) 1536-1542
  CrossrefPubMedGoogle Scholar
• 73 Nilsson TA, Hedman LR, Ahlqvist JB. Dental student skill retention eight months after simulator-supported training in oral radiology. J Dent Educ 2011; 75 (05) 679-684
  CrossrefPubMedGoogle Scholar
• 74 Soltanimehr E, Bahrampour E, Imani MM, Rahimi F, Almasi B, Moattari M. Effect of virtual versus traditional education on theoretical knowledge and reporting skills of dental students in radiographic interpretation of bony lesions of the jaw. BMC Med Educ 2019; 19 (01) 233
  CrossrefPubMedGoogle Scholar
• 75 Wang D, Zhang Y, Hou J. et al. IDental: a haptic-based dental simulator and its preliminary user evaluation. IEEE Trans Haptics 2012; 5 (04) 332-343
  CrossrefPubMedGoogle Scholar
• 76 Yamaguchi S, Yoshida Y, Noborio H, Murakami S, Imazato S. The usefulness of a haptic virtual reality simulator with repetitive training to teach caries removal and periodontal pocket probing skills. Dent Mater J 2013; 32 (05) 847-852
  CrossrefPubMedGoogle Scholar
• 77 Papadopoulos L, Pentzou AE, Louloudiadis K, Tsiatsos TK. Design and evaluation of a simulation for pediatric dentistry in virtual worlds. J Med Internet Res 2013; 15 (11) e240
  CrossrefPubMedGoogle Scholar
• 78 Mladenovic R, Dakovic D, Pereira L, Matvijenko V, Mladenovic K. Effect of augmented reality simulation on administration of local anaesthesia in paediatric patients. Eur J Dent Educ 2020; 24 (03) 507-512
  CrossrefPubMedGoogle Scholar
• 79 Zafar S, Lai Y, Sexton C, Siddiqi A. Virtual reality as a novel educational tool in pre-clinical paediatric dentistry training: students’ perceptions. Int J Paediatr Dent 2020; 30 (06) 791-797
  CrossrefPubMedGoogle Scholar
• 80 Zafar S, Siddiqi A, Yasir M, Zachar JJ. Pedagogical development in local anaesthetic training in paediatric dentistry using virtual reality simulator. Eur Arch Paediatr Dent 2021; 10: 1-8
  Google Scholar
• 81 Naser-ud-Din S. Introducing scenario based learning interactive to postgraduates in UQ Orthodontic Program. Eur J Dent Educ 2015; 19 (03) 169-176
  CrossrefPubMedGoogle Scholar
• 82 Allaire JL. Assessing critical thinking outcomes of dental hygiene students utilizing virtual patient simulation: a mixed methods study. J Dent Educ 2015; 79 (09) 1082-1092
  CrossrefPubMedGoogle Scholar
• 83 Marei HF, Al-Eraky MM, Almasoud NN, Donkers J, Van Merrienboer JJ. The use of virtual patient scenarios as a vehicle for teaching professionalism. Eur J Dent Educ 2018; 22 (02) e253-e260
  CrossrefPubMedGoogle Scholar
• 84 El M Tantawi, Sadaf S, AlHumaid J. Using gamification to develop academic writing skills in dental undergraduate students. Eur J Dent Educ 2018; 22 (01) 15-22
  CrossrefPubMedGoogle Scholar
• 85 Takagi D, Hayashi M, Iida T. et al. Effects of dental students’ training using immersive virtual reality technology for home dental practice. Educ Gerontol 2019; 45 (11) 670-680
  CrossrefGoogle Scholar
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