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. 2018 Feb;34(2):192-200.
doi: 10.1016/j.dental.2017.10.003. Epub 2017 Oct 27.

3D printed versus conventionally cured provisional crown and bridge dental materials

Anthony Tahayeri  1 MaryCatherine Morgan  1 Ana P Fugolin  1 Despoina Bompolaki  1 Avathamsa Athirasala  1 Carmem S Pfeifer  1 Jack L Ferracane  1 Luiz E Bertassoni  2
Affiliations

3D printed versus conventionally cured provisional crown and bridge dental materials

Anthony Tahayeri et al. Dent Mater. 2018 Feb.

Abstract

Objectives: To optimize the 3D printing of a dental material for provisional crown and bridge restorations using a low-cost stereolithography 3D printer; and compare its mechanical properties against conventionally cured provisional dental materials.

Methods: Samples were 3D printed (25×2×2mm) using a commercial printable resin (NextDent C&B Vertex Dental) in a FormLabs1+ stereolithography 3D printer. The printing accuracy of printed bars was determined by comparing the width, length and thickness of samples for different printer settings (printing orientation and resin color) versus the set dimensions of CAD designs. The degree of conversion of the resin was measured with FTIR, and both the elastic modulus and peak stress of 3D printed bars was determined using a 3-point being test for different printing layer thicknesses. The results were compared to those for two conventionally cured provisional materials (Integrity®, Dentsply; and Jet®, Lang Dental Inc.).

Results: Samples printed at 90° orientation and in a white resin color setting was chosen as the most optimal combination of printing parameters, due to the comparatively higher printing accuracy (up to 22% error), reproducibility and material usage. There was no direct correlation between printing layer thickness and elastic modulus or peak stress. 3D printed samples had comparable modulus to Jet®, but significantly lower than Integrity®. Peak stress for 3D printed samples was comparable to Integrity®, and significantly higher than Jet®. The degree of conversion of 3D printed samples also appeared higher than that of Integrity® or Jet®.

Significance: Our results suggest that a 3D printable provisional restorative material allows for sufficient mechanical properties for intraoral use, despite the limited 3D printing accuracy of the printing system of choice.

Keywords: 3D printing; CAD/CAM; Digital dentistry; Provisional restoration; Temporary crown and bridge.

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Figures

Figure 1
Figure 1
CAD designs for test specimens at (A) 0, (B) 15, (C) 45 and (D) 90° printing orientations. Corresponding polymer structures 3D printed at (E) 0, (F) 15, (G) 45 and (H) 90° printing orientations.
Figure 2
Figure 2
Printing accuracy in (A) length, (B) width and (C) thickness as a function of orientation of the printed bar. Samples were printed using the “white” resin setting and 100 μm layer thickness. The columns connected by bars were significantly different.
Figure 3
Figure 3
Printing accuracy in (A) length, (B) width and (C) thickness relative to resin color setting. Samples were 3D printed with 100 μm layer thickness and at 90° orientation. The columns connected by bars were significantly different.
Figure 4
Figure 4
Laser intensity for different resin color settings.
Figure 5
Figure 5
Mechanical properties for samples 3D printed with 25, 50 and 100 μm layer thickness.
Figure 6
Figure 6
Laser intensity for 25, 50 and 100 μm layer thickness printing parameter.
Figure 7
Figure 7
(A) Elastic modulus and (B) peak stress for 3D printed specimens versus Integrity and Jet specimens.
Figure 8
Figure 8
Representative 2D mapping of degree of conversion generated based on spectra obtained at every 50 μm along 3 separate lines (20 measurements in y) on a cross-sectioned surface of each individual specimens.
See this image and copyright information in PMC

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