Optimizing quality of dental carving by preclinical dental students through anatomy theory reinforcement

Knowledge of dental anatomy is of great importance in the practice of dentistry, especially in oral rehabilitation, because without this knowledge, professional practice is not possible. Dental carving plays a major role in training dental students as it develops their manual dexterity. This randomized controlled trial aimed to evaluate the influence of didactic‐theoretical reinforcement on the theoretical and practical knowledge of dental anatomy of preclinical students by examining the quality of the anatomical restorations performed by these students before and after a didactic‐theoretical reinforcement. For the evaluation of theoretical knowledge, a questionnaire with closed questions about dental anatomy was used. To evaluate the effect of didactic reinforcement on dental carvings, two groups of 15 preclinical students were assessed. Experimental group (G1) received a three‐hour theoretical tutoring on dental anatomy, while the control group (G2) did not. The dental carving scores obtained by the two different groups were compared using Student's t‐test. Cohen's d was used to estimate the effect sizes between groups. The frequency of correct answers given for each theoretical knowledge question was compared in each group using Fisher's exact test. T‐test was also used to compare the means of the two groups' final scores of theoretical evaluations. To compare these final scores obtained in both carving and theoretical tests, a principal component analysis was performed with different items assessed in each test to obtain factor loading scores and a final weighted score, where factor loadings were considered for each item. Weighted scores were compared using t‐test. Also, scores obtained during the head and neck course were assessed and compared using t‐test. Spearman's correlation test was used to assess the correlation between scores obtained prior to the anatomy course and scores obtained in the dental carving exercise. The theoretical evaluation revealed no significant difference between the grades (mean ± SD) of G1 (85.1 ± 6.6%) and G2 (86.2 ± 9.1%) with the grades of a baseline test that was previously obtained when students submitted to the study (P = 0.725). Regarding the tooth carving assessment, the dental carving quality by students of G1 has significantly improved, except for tooth #23 (P = 0.096). Theoretical reinforcement of dental anatomy seems to improve the students' carving performance but does not enhance their knowledge about dental anatomy. Anat Sci Educ 11: 377–384. © 2017 American Association of Anatomists.

[1]  S. McHanwell Teaching Anatomical Sciences to Dental Students , 2020, Teaching Anatomy.

[2]  O. R. Anderson,et al.  Students' perceptions of a blended learning experience in dental education , 2018, European journal of dental education : official journal of the Association for Dental Education in Europe.

[3]  T. Raupach,et al.  The effect of repeated testing vs repeated practice on skills learning in undergraduate dental education , 2018, European journal of dental education : official journal of the Association for Dental Education in Europe.

[4]  Mahmoud M. Bakr,et al.  Anatomical sciences: A foundation for a solid learning experience in dental technology and dental prosthetics , 2017, Anatomical sciences education.

[5]  F. Alsoleihat,et al.  Is Soap Carving in Dental Anatomy Predictive for Clinical Dental Students’ Performance in Operative Dentistry? , 2017 .

[6]  T. Culp,et al.  Communicating with Dental Laboratories , 2017 .

[7]  B. Willershausen,et al.  Catalogue of Interactive Learning Objectives to improve an Integrated Medical and Dental Curriculum. , 2016, The journal of contemporary dental practice.

[8]  R. Hussain Self-assessment of dental Students in Wax Carving Course in Syrian Private University , 2016 .

[9]  Mahmoud M. Bakr,et al.  Flipping a Dental Anatomy Course: A Retrospective Study Over Four Years , 2016 .

[10]  Mahmoud M. Bakr,et al.  Digital Cadavers: Online 2D Learning Resources Enhance Student Learning in Practical Head and Neck Anatomy within Dental Programs , 2016 .

[11]  E. Yıldız,et al.  Esthetic and functional management of diastema , 2016 .

[12]  Claudio Violato,et al.  A meta‐analysis of the educational effectiveness of three‐dimensional visualization technologies in teaching anatomy , 2015, Anatomical sciences education.

[13]  Y. Oweis,et al.  Students’ Perceptions of Dental Anatomy Course at The University of Jordan , 2015 .

[14]  R. Lund,et al.  Comparative Effectiveness of Dental Anatomy Carving Pedagogy: A Systematic Review. , 2015, Journal of dental education.

[15]  Guido Heydecke,et al.  A model of blended learning in a preclinical course in prosthetic dentistry. , 2015, Journal of dental education.

[16]  S. Sowmya,et al.  Knowledge, attitude and practice of tooth morphology among dental students , 2015 .

[17]  Pascal Magne,et al.  A new approach to the learning of dental morphology, function, and esthetics: the "2D-3D-4D" concept. , 2015, The international journal of esthetic dentistry.

[18]  Heather Alexander,et al.  Students’ evaluation of a 3DVR haptic device (Simodont®). Does early exposure to haptic feedback during preclinical dental education enhance the development of psychomotor skills? , 2014 .

[19]  Andréa Dias Neves Lago,et al.  Theoretical knowledge versus practical performance in dental carving: preliminary study , 2014 .

[20]  D. Buchaim,et al.  Multidisciplinary Approach in the Teaching of Dental Sculpture and Anatomy , 2014 .

[21]  J. Foley,et al.  Self-directed study and carving tooth models for learning tooth morphology: perceptions of students at the University of Aberdeen, Scotland. , 2013, Journal of dental education.

[22]  M. D'Eon,et al.  Efficacy of a step-by-step carving technique for dental students. , 2013, Journal of dental education.

[23]  B. Scheven Perceived relevance of oral biology by dental students. , 2012, European journal of dental education : official journal of the Association for Dental Education in Europe.

[24]  L. Leisnert,et al.  Improving teamwork between students from two professional programmes in dental education , 2012, European journal of dental education : official journal of the Association for Dental Education in Europe.

[25]  A. Obrez,et al.  Teaching clinically relevant dental anatomy in the dental curriculum: description and assessment of an innovative module. , 2011, Journal of dental education.

[26]  P. Pospiech,et al.  Introducing and evaluating MorphoDent, a Web-based learning program in dental morphology. , 2010, Journal of dental education.

[27]  Daniel R. Montello,et al.  How spatial abilities enhance, and are enhanced by, dental education , 2009 .

[28]  E. Kay,et al.  The anatomy of a new dental curriculum , 2008, BDJ.

[29]  J. Türp,et al.  Dental occlusion: a critical reflection on past, present and future concepts. , 2008, Journal of oral rehabilitation.

[30]  Sergio Rubinstein,et al.  The art and science of the direct posterior restoration: recreating form, color, and translucency. , 2007, The Alpha omegan.

[31]  S. Gansky,et al.  Reliability and validity of a manual dexterity test to predict preclinical grades. , 2004, Journal of dental education.

[32]  L. Abbey,et al.  Equivalence study of a dental anatomy computer-assisted learning program. , 2004, Journal of dental education.

[33]  Kenneth L Allen,et al.  Integrating dental anatomy and biomaterials: an innovative use of composite resin. , 2004, General dentistry.

[34]  M. Vitti,et al.  Educational material of dental anatomy applied to study the morphology of permanent teeth. , 2004, Brazilian dental journal.

[35]  M. Sneed,et al.  Issues regarding practical validity and gender bias of the Perceptual Abilities Test (PAT). , 2003, Journal of dental education.