The Effect of Different Wax Pattern Fabrication Techniques on the Marginal Fit of Customized Lithium Disilicate Implant Abutments

Taha, Doaa; Nour, M.; Zohdy, Maged; El-Etreby, Amr; Hamdy, Amina; Morsi, Tarek Salah

doi:10.1111/jopr.13112

Cited by 16 publications

(20 citation statements)

References 26 publications

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“…The CAD/CAM process manufactures dental prostheses in the order of scanning, CAD, and CAM processes [7,8]. The steps of CAD/CAM workflow are as follows: acquire a virtual work model using a 3-dimensional (3D) scanner and produce a working cast using a 3D printer, milling machine, or design a prosthesis in CAD software without a model and then use 3D printing and milling technologies to fabricate dental prostheses [9,10].…”

Section: Introductionmentioning

confidence: 99%

Comparison of Intaglio Surface Trueness of Interim Dental Crowns Fabricated with SLA 3D Printing, DLP 3D Printing, and Milling Technologies

Lee

Lee²

2021

Healthcare

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This study aimed to evaluate the intaglio surface trueness of interim dental crowns fabricated with three 3-dimensional (3D) printing and milling technologies. Dental crown was designated and assigned as a computer-aided design (CAD) reference model (CRM). Interim dental crowns were fabricated based on CRM using two types of 3D printer technologies (stereolithography apparatus and digital light processing) and one type of milling machine (n = 15 per technology). The fabricated interim dental crowns were obtained via 3D modeling of the intaglio surface using a laboratory scanner and designated as CAD test models (CTMs). The alignment and 3D comparison of CRM and CTM were performed based on the intaglio surface using a 3D inspection software program (Geomagic Control X). Statistical analysis was validated using one-way analysis of variance and Tukey HSD test (α = 0.05). There were significant differences in intaglio surface trueness between the three different fabrication technologies, and high trueness values were observed in the milling group (p < 0.05). In the milling group, there was a significant difference in trueness according to the location of the intaglio surface (p < 0.001). In the manufacturing process of interim dental crowns, 3D printing technologies showed superior and uniform manufacturing accuracy than milling technology.

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Section: Introductionmentioning

confidence: 99%

Comparison of Intaglio Surface Trueness of Interim Dental Crowns Fabricated with SLA 3D Printing, DLP 3D Printing, and Milling Technologies

Lee

Lee²

2021

Healthcare

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“…The paradigm shift in recently introduced digital workflow of oral implantology and CAD/ CAM technology has reached an advanced level of development. 24 The overlap between these two advanced categories in dentistry in addition to the innovative enhancement in all-ceramic materials and polymer-based materials led to the introduction of novel treatment strategies and concepts for replacement of missing single tooth through implant-supported restorations. 45 The selection of implant abutments which represent the link between osseo-integrated implant fixtures and implant superstructure is crucial in gaining functional and esthetic rehabilitation.…”

Section: Discussionmentioning

confidence: 99%

“…Moreover, within the pressing technique itself, the step of the wax pattern construction could be designed with different technologies such as manual conventional technique, subtractive CAD/CAM technique as well as the additive 3D manufacturing technique. 24 In this study, the two techniques for construction of lithium disilicate E.max ceramic were selected: the CAD/CAM technique and the pressing technique using the 3D printing for wax pattern fabrication. The E.max Press abutments showed higher pullout retention values than E.max CAD abutments and the difference was statistically significant.…”

Section: Discussionmentioning

confidence: 99%

“…The abutments were designed with a standardized dimension according to the dimensions of prepared upper second premolar as follows: 12 mm occlusogingival height, 6.5mm bucco-lingual width, 5.5 mm mesio-distal width, 0.5 mm chamfer finish line and 2.5mm screw channel. 24 (Fig. 2).…”

Section: Methodsmentioning

confidence: 97%

“…17 CAD/ CAM technology is not only restricted to subtractive manufacturing where the crown or abutment can be milled or grinded from a block or a disc, but also additive manufacturing can be used to fabricate a wax pattern, which in turn, can be used either by heat-pressing or compression moulding techniques to fabricate the superstructure. 24 Due to the huge advancement in technologies and materials, the use of Ti-base nowadays ranges from single tooth replacement to full-arch prostheses with a plethora of dental materials available for each purpose. 25 When used as abutments on Ti-base, zirconia has shown good results and high fracture resistance 26 .…”

Section: Introductionmentioning

confidence: 99%

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Effect of different fabrication materials and techniques on the retention of implant meso-structures to Ti-base abutments

El-Sayed

Elbanna

2021

Egyptian Dental Journal

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Objectives:The aim of this in-vitro study was to evaluate the effect of the material and the manufacturing technique on the retention of the meso-structure to the Ti-base after artificial thermocycling aging. Materials and Methods:Forty implant analogs compatible with the Noble Biocare Replace CC regular platform implant system (Dess, Spain) were used in this study to simulate the replacement of an upper second premolar. Implant analogues were placed in epoxy resin moulds. Ti-bases were screwed to the implant analogues. Ti-bases of different groups were scanned using CAD/ CAM scanner and the design of implant abutments was performed using CAD/CAM software. The abutment had two holes with 1 mm diameter in the mesial and distal surfaces to engage a stainlesssteel wire to facilitate the pull-out testing. The samples were divided into 5 equal groups (n=8) according to the material and technique of construction of the meso-structure as follows: Group I (Zr CAD): CAD/CAM milled zirconia abutments, Group II (E.max Press): Pressable lithium disilicate abutments with 3D printed resin pattern, Group III (E.max CAD): CAD/CAM milled lithium disilicate abutments, Group IV (PEEK CAD):CAD/CAM milled PEEK abutments, Group V (PEEK Press): 3D-printed resin pattern were fabricated and PEEK (BioHPP, Bredent, Germany) was directly pressed on the Ti-base using a thermal moulding machine (For 2 Press, Bredent, Germany) to fabricate the abutments. The samples of each group were surface treated and cemented to the respective Ti-bases according to the manufacturer's instructions of each material. All the samples were subjected to a total of 10,000 thermal cycles between 5°C and 55°C to simulate thermal fluctuations intraorally. All samples were subjected to pull-out retention test after thermal aging to separate the abutments from the Ti-base. After pull-out testing, the surfaces of the Tibases and the internal surfaces of the abutments were photographed under high magnification using digital camera to analyze the mode of failure.

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Additive Manufacturing Procedures and Clinical Applications in Restorative Dentistry

Revilla‐León¹,

Zandinejad²

2022

Clinical Applications of Digital Dental Technology

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The Effect of Different Wax Pattern Fabrication Techniques on the Marginal Fit of Customized Lithium Disilicate Implant Abutments

Cited by 16 publications

References 26 publications

Comparison of Intaglio Surface Trueness of Interim Dental Crowns Fabricated with SLA 3D Printing, DLP 3D Printing, and Milling Technologies

Comparison of Intaglio Surface Trueness of Interim Dental Crowns Fabricated with SLA 3D Printing, DLP 3D Printing, and Milling Technologies

Effect of different fabrication materials and techniques on the retention of implant meso-structures to Ti-base abutments

Additive Manufacturing Procedures and Clinical Applications in Restorative Dentistry

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