Sage Journals: Discover world-class research

Abstract

BACKGROUND:

Clinically, apical barrier procedure can be adopted to create an immediate artificial barrier for tooth with an open apex. Given that the quality of the barrier is crucial, the apical barrier procedure is known for its high technical sensitivity, posing significant learning challenges for dental students. Therefore, a new dental teaching model not only effectively enhances the future clinical skills of dental students but also benefits a wider range of patients.

OBJECTIVE:

A new dental model for simulating apical barrier procedure in vitro, is helpful for dental students to practice apical barrier procedure. This study aims to design, assess, and evaluate the feasibility of a three-dimensional (3D) printed apical barrier model for pre-clinical dental education.

METHODS:

A novel 3D-printed apical barrier model was developed, consisting of a tooth model and a matching blind box. Total 200 3D-printed apical barrier models were used to train dental students, and fifty fifth-year dental students participated in this voluntary hands-on course. Each student performed apical barrier procedures on four 3D-printed models. The outcome of the first model served as the representative result for the “direct barrier group”, whereas the outcome of the fourth model represented the result of the “post-training barrier group”. The quality of the apical barrier procedure was assessed through X-ray examination, and a questionnaire was used to evaluate the 3D-printed model’s benefits, with scores ranging from 1 (strongly agree) to 5 (strongly disagree).

RESULTS:

The overall rating for the 3D-printed model was 2.0 $\pm$ 0.6. The model was noted for its high degree of realism, ease of use, and practical applicability. Post-training assessments showed significant improvements in the density of apical barrier fillings ( $P<$ 0.05), reduction in underfilling rates ( $P<$ 0.05), and decrease in overfilling distances ( $P<$ 0.05). Students overwhelmingly agreed that the model was beneficial for training in apical barrier procedures (1.06 $\pm$ 0.24), helped identify their shortcomings (1.62 $\pm$ 0.53), and improved their operational skills (1.90 $\pm$ 0.51).

CONCLUSIONS:

Both the questionnaire feedback and the quality of the fillings confirmed the feasibility and efficacy of the 3D-printed apical barrier model for dental education. The students had the possibility to learn the correct apical barrier procedure on printed dental models.

Keywords

3D printing technology dental education apical barrier procedure hands-on training self-assessment

Get full access to this article

View all access options for this article.

References

. Cohen’s Pathways of the Pulp. St. Louis: Elsevier; 2016.

Reymus

Fotiadou

Kessler

Heck

Hickel

Diegritz

. 3D printed replicas for endodontic education. International Endodontic Journal. 2019; 52(1): 123-30.

Boonsiriphant

Al-Salihi

Holloway

Schneider

. The use of 3D printed tooth preparation to assist in teaching and learning in preclinical fixed prosthodontics courses. Journal of Prosthodontics. 2019; 28(2): e545-e7.

Kustra

Dobroś

Zarzecka

. Making use of three-dimensional models of teeth, manufactured by stereolithographic technology, in practical teaching of endodontics. European Journal of Dental Education. 2021; 25(2): 299-304.

Höhne

Schmitter

. 3D printed teeth for the preclinical education of dental students. Journal of Dental Education. 2019; 83(9): 1100-6.

Höhne

Schwarzbauer

Schmitter

. 3D printed teeth with enamel and dentin layer for educating dental students in crown preparation. Journal of Dental Education. 2019; 83(12): 1457-63.

Höhne

Schwarzbauer

Schmitter

. Introduction of a new teaching concept for crown preparation with 3D printed teeth. European Journal of Dental Education. 2020; 24(3): 526-34.

Höhne

Jentzsch

Schmitter

MJEJoDE

. The “Painting by Numbers Method” for education of students in crown preparation. 2021; 25(2): 261-70.

Höhne

Rammler

Schmitter

. 3D printed teeth with included veneer preparation guide. Journal of Prosthodontics. 2021; 30(1): 51-6.

10.

Kröger

Dekiff

Dirksen

. 3D printed simulation models based on real patient situations for hands-on practice. European Journal of Dental Education. 2017; 21(4): e119-e25.

11.

Zeng

Dong

Zhang

Zheng

Wang

, et al. 3D-printed coloured tooth model for inlay preparation in pre-clinical dental education. European Journal of Dental Education. 2024; 28(2): 481-9.

12.

Robberecht

Chai

Dehurtevent

Marchandise

Bécavin

Hornez

, et al. A novel anatomical ceramic root canal simulator for endodontic training. European Journal of Dental Education. 2017; 21(4): e1-e6.

13.

Al Ansary

MAD

Day

Duggal

Brunton

. Interventions for treating traumatized necrotic immature permanent anterior teeth: inducing a calcific barrier & root strengthening. Dental Traumatology. 2009; 25(4): 367-79.

14.

Trope

. Treatment of the immature tooth with a non–vital pulp and apical periodontitis. Dental Clinics. 2010; 54(2): 313-24.

15.

Tran

Glickman

Woodmansey

. Comparative analysis of calcium silicate–based root filling materials using an open apex model. Journal of Endodontics. 2016; 42(4): 654-8.

16.

Höhne

Dickhaut

Schmitter

. Introduction of a new teaching concept for dentin post preparation with 3D printed teeth. European Journal of Dental Education. 2020; 24(3): 499-506.

17.

Estefan

El Batouty

Nagy

Diogenes

. Influence of age and apical diameter on the success of endodontic regeneration procedures. Journal of Endodontics. 2016; 42(11): 1620-5.

18.

Fang

Wang

Zhu

Yang

Meng

. Influence of apical diameter on the outcome of regenerative endodontic treatment in teeth with pulp necrosis: a review. Journal of Endodontics. 2018; 44(3): 414-31.

19.

Gillen

Looney

L-S

Loushine

Weller

Loushine

, et al. Impact of the quality of coronal restoration versus the quality of root canal fillings on success of root canal treatment: a systematic review and meta-analysis. Journal of Endodontics. 2011; 37(7): 895-902.

20.

Eleftheriadis

Lambrianidis

. Technical quality of root canal treatment and detection of iatrogenic errors in an undergraduate dental clinic. International Endodontic Journal. 2005; 38(10): 725-34.

Three-dimensional printed apical barrier model technology for pre-clinical dental education

Abstract

BACKGROUND:

OBJECTIVE:

METHODS:

RESULTS:

CONCLUSIONS:

Keywords

Get full access to this article

References