Fracture load of 3D-printed fixed dental prostheses compared with milled and conventionally fabricated ones: the impact of resin material, build direction, post-curing, and artificial aging—an in vitro study

Fracture load of 3D-printed fixed dental prostheses compared with milled and conventionally fabricated ones: the impact of resin material, build direction, post-curing, and artificial aging—an in vitro study

Objective To investigate the impact of 3D print material, build direction, post-curing, and artificial aging on fracture load of fixed dental prostheses (FDPs). Materials and methods Three-unit FDPs were 3D-printed using experimental resin (EXP), NextDent C&B (CB), Freeprint temp (FT), and 3Delt...

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Bibliographic Details
Published in:Clinical oral investigations Vol. 24; no. 2; pp. 701 - 710
Main Authors: Reymus, Marcel, Fabritius, Rosalie, Keßler, Andreas, Hickel, Reinhard, Edelhoff, Daniel, Stawarczyk, Bogna
Format: Journal Article
Language:English
Published: Berlin/Heidelberg Springer Berlin Heidelberg 01-02-2020
Springer Nature B.V
Subjects:
Aging
Aluminum
Dental Materials
Dental Prosthesis
Dental prosthetics
Dental Restoration Failure
Dental restorative materials
Dental Stress Analysis
Dentistry
Kruskal-Wallis test
Load
Materials Testing
Medicine
Original Article
Printing, Three-Dimensional
Prostheses
Artificial aging
Fracture load
Post-curing
Build direction
3D printing
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Summary:Objective To investigate the impact of 3D print material, build direction, post-curing, and artificial aging on fracture load of fixed dental prostheses (FDPs). Materials and methods Three-unit FDPs were 3D-printed using experimental resin (EXP), NextDent C&B (CB), Freeprint temp (FT), and 3Delta temp (DT). In the first part, the impacts of build direction and artificial aging were tested. FDPs were manufactured with their long-axis positioned either occlusal, buccal, or distal to the printer’s platform. Fracture load was measured after artificial aging (H 2 O: 21 days, 37 °C). In the second part, the impact of post-curing was tested. FDPs were post-cured using Labolight DUO, Otoflash G171, and LC-3DPrint Box. While the positive control group was milled from TelioCAD (TC), the negative control group was fabricated from a conventional interim material Luxatemp (LT). The measured initial fracture loads were compared with those after artificial aging. Each subgroup contained 15 specimens. Data were analyzed using Kolmogorov-Smirnov test, one-way ANOVA followed by Scheffé post hoc test, t test, Kruskal-Wallis test, and Mann-Whitney U test ( p  < 0.05). The univariate ANOVA with partial eta squared ( η P 2 ) was used to analyze the impact of test parameters on fracture load. Results Specimens manufactured with their long-axis positioned distal to the printer’s platform showed higher fracture load than occlusal ones ( p  = 0.049). The highest values were observed for CB, followed by DT ( p  < 0.001). EXP showed the lowest values, followed by FT ( p  < 0.001). After artificial aging, a decrease of fracture load for EXP ( p  < 0.001) and DT ( p  < 0.001) was observed. The highest impact on values was exerted by interactions between 3D print material and post-curing unit ( η P 2  = 0.233, p  < 0.001), followed by the 3D print material ( η P 2  = 0.219, p  < 0.001) and curing device ( η P 2  = 0.108, p  < 0.001). Conclusions Build direction, post-curing, artificial aging, and material have an impact on the mechanical stability of printed FDPs. Clinical relevance The correct post-curing strategy is mandatory to ensure mechanical stability of 3D-printed FDPs. Additively manufactured FDPs are more prone to artificial aging than conventionally fabricated ones.
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ISSN:1432-6981
1436-3771
DOI:10.1007/s00784-019-02952-7