PURPOSE. The accuracy of denture bases was compared among injection molding, milling, and rapid prototyping (RP) fabricating method.
MATERIALS AND METHODS. The maxillary edentulous master cast was fabricated and
round shaped four notches were formed. The cast was duplicated to ten casts and scanned. In the injection molding method, designed denture bases were milled from a wax block and fabricated using SR Ivocap injection system. Denture bases were milled from a pre-polymerized block in the milling method. In the RP method, denture bases were printed and post-cured. The intaglio surface of the base was scanned and surface matching software was used to measure inaccuracy. Measurements were performed between four notches and two points in the mid-palatal suture to evaluate inaccuracy. The palatine rugae resolution was evaluated. One-way analysis of variance was used for statistical analysis at α=.05.
RESULTS. No statistically significant differences in distances among four notches (P>.05). The accuracy of the injection molding method was lower than those of the other methods in two points of the mid-palatal suture significantly (P<.05). The degree of palatine rugae resolution was significantly higher in the injection molding method than that in other methods (P<.05).
CONCLUSION. The overall accuracy of the denture base is higher in milling and RP method than the injection molding method. The degree of fine reproducibility is higher in the injection molding method than the milling or RP method.
[J Adv Prosthodont 2019;11:55-64]

PURPOSE. The accuracy of denture bases was compared among injection molding, milling, and rapid prototyping (RP) fabricating method.
MATERIALS AND METHODS. The maxillary edentulous master cast was fabricated and
round shaped four notches were formed. The cast was duplicated to ten casts and scanned. In the injection molding method, designed denture bases were milled from a wax block and fabricated using SR Ivocap injection system. Denture bases were milled from a pre-polymerized block in the milling method. In the RP method, denture bases were printed and post-cured. The intaglio surface of the base was scanned and surface matching software was used to measure inaccuracy. Measurements were performed between four notches and two points in the mid-palatal suture to evaluate inaccuracy. The palatine rugae resolution was evaluated. One-way analysis of variance was used for statistical analysis at α=.05.
RESULTS. No statistically significant differences in distances among four notches (P>.05). The accuracy of the injection molding method was lower than those of the other methods in two points of the mid-palatal suture significantly (P<.05). The degree of palatine rugae resolution was significantly higher in the injection molding method than that in other methods (P<.05).
CONCLUSION. The overall accuracy of the denture base is higher in milling and RP method than the injection molding method. The degree of fine reproducibility is higher in the injection molding method than the milling or RP method.
[J Adv Prosthodont 2019;11:55-64]

1 Groth C, "Three-dimensional printing technology" 48 : 475-485, 2014

2 Jacob RF, "The traditional therapeutic paradigm : complete denture therapy" 79 : 6-13, 1998

3 Johnson DL, "The plastic postpalatal denture seal" 18 : 457-462, 1987

4 Darvell BW, "The physical mechanisms of complete denture retention" 189 : 248-252, 2000

5 Munari LS, "Stress distribution in a premolar 3D model with anisotropic and isotropic enamel" 53 : 751-758, 2015

6 Braian M, "Production tolerance of additive manufactured polymeric objects for clinical applications" 32 : 853-861, 2016

7 Sykora O, "Posterior palatal seal adaptation : influence of processing technique, palate shape and immersion" 20 : 19-31, 1993

8 Matsuda T, "Partdigitizing system of impression and interocclusal record for complete denture fabrication" 25 : 503-509, 2016

9 Allen S, "On the computation of part orientation using support structures in layered manufacturing" 259-269, 1994

10 Pryor WJ, "Injection molding of plastics for dentures" 29 : 1400-1408, 1942

11 Ender A, "Influence of scanning strategies on the accuracy of digital intraoral scanning systems" 16 : 11-21, 2013

12 Schaefer O, "Impact of digital impression techniques on the adaption of ceramic partial crowns in vitro" 42 : 677-683, 2014

13 Infante L, "Fabricating complete dentures with CAD/CAM technology" 111 : 351-355, 2014

14 Puebla K, "Effects of environmental conditions, aging, and build orientations on the mechanical properties of ASTM type I specimens manufactured via stereolithography" 18 : 374-388, 2012

15 Alharbi N, "Effects of build direction on the mechanical properties of 3D-printed complete coverage interim dental restorations" 115 : 760-767, 2016

16 Kawara M, "Distortion behavior of heat-activated acrylic denture-base resin in conventional and long, low-temperature processing methods" 77 : 1446-1453, 1998

17 Huggett R, "Dimensional accuracy and stability of acrylic resin denture bases" 68 : 634-640, 1992

18 Plooij JM, "Digital three-dimensional image fusion processes for planning and evaluating orthodontics and orthognathic surgery. A systematic review" 40 : 341-352, 2011

19 Johnson DL, "Contours of the edentulous palate" 113 : 35-40, 1986

20 Bidra AS, "Computer-aided technology for fabricating complete dentures : systematic review of historical background, current status, and future perspectives" 109 : 361-366, 2013

21 Wimmer T, "Complete denture fabrication supported by CAD/CAM" 115 : 541-546, 2016

22 Parvizi A, "Comparison of the dimensional accuracy of injection-molded denture base materials to that of conventional pressure-pack acrylic resin" 13 : 83-89, 2004

23 McLaughlin JB, "Comparison of fit of dentures fabricated by traditional techniques versus CAD/CAM technology" 2017

24 Goodacre BJ, "Comparison of denture base adaptation between CAD-CAM and conventional fabrication techniques" 116 : 249-256, 2016

25 Lee CJ, "Comparative adaptation accuracy of acrylic denture bases evaluated by two different methods" 29 : 411-417, 2010

26 Steinmassl O, "CAD/CAM produces dentures with improved fit" 22 : 2829-2835, 2018

27 Srinivasan M, "CAD/CAM milled removable complete dentures : an in vitro evaluation of trueness" 21 : 2007-2019, 2017

28 Goodacre CJ, "CAD/CAM fabricated complete dentures : concepts and clinical methods of obtaining required morphological data" 107 : 34-46, 2012

29 Revilla-León M, "Additive manufacturing technologies used for processing polymers: Current status and potential application in prosthetic dentistry" 2018

30 Petrovic V, "Additive layered manufacturing : sectors of industrial application shown through case studies" 49 : 1061-1079, 2011

31 Jacobson TE, "A contemporary review of the factors involved in complete dentures. Part III: support" 49 : 306-313, 1983

32 Jacobson TE, "A contemporary review of the factors involved in complete dentures. Part II: stability" 49 : 165-172, 1983

33 Jacobson TE, "A contemporary review of the factors involved in complete denture retention, stability, and support. Part I: retention" 49 : 5-15, 1983

34 Maeda Y, "A CAD/CAM system for removable denture. Part I: Fabrication of complete dentures" 7 : 17-21, 1994

35 Kuesel AC, "31P NMR studies of cultured human tumor cells. Influence of pH on phospholipid metabolite levels and the detection of cytidine 5’-diphosphate choline" 3 : 78-89, 1990