Novel polymeric support materials for jetting based additive manufacturing processes

Fahad, Muhammad; Dickens, Phill; Gilbert, Marianne

doi:10.1108/13552541311323245

Cited by 43 publications

(42 citation statements)

References 30 publications

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“…Alharbi et al reported that materials printed vertically (90°) had higher compressive strength that the ones printed horizontally (0°). Osman et al showed that using direct light processing technologies, the recommended build angle for 3D printed restorations was 135°, which may require the use of supportive structures . Tahayeri et al also showed the importance of printing orientation, but they included resin color setting as an important factor for printing accuracy.…”

Section: Discussionmentioning

confidence: 99%

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Laboratory workflow to obtain long‐term injected resin composite interim restorations from an additive manufactured esthetic diagnostic template

Piedra‐Cascón

Nuñez²,

Díez

et al. 2018

J Esthet Restor Dent

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Objective An analogue and digital workflow for the fabrication of a diagnostic 3D printed polymer template and its duplication for long‐term injected composite resin interim restorations is described, because of the lack of scientific evidence in 3‐dimensional (3D) printing applied to dentistry in terms of printer technology, printer parameters, postpolymerization processes, and material characteristics. In addition, in the case of 3D printed temporary resins, they cannot be relined successfully and its mechanical properties in the mouth have not been tested yet. Conclusions The main benefits of this approach relate to the improvement of clinical and laboratory procedures, as conventional waxing is eliminated, conventional master casts are not needed and the process is entirely automatized, improving the workflow, with minimal intervention of the laboratory technician. Clinical Significance The additive manufactured diagnostic template represents the materialization of the digital diagnostic waxing and provides a powerful tool to visualize the digital diagnostic waxing in the patient's mouth and face. Furthermore, the diagnostic 3D printed template can be used for multiple applications including interim restorations, radiographical, or surgical guide fabrication. The duplication technique described provides a predictable workflow to obtain long‐term injected resin composite restorations from an additive manufactured esthetic diagnostic template, improving the laboratory and chairside procedures.

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Section: Discussionmentioning

confidence: 99%

“…In the early 1980s, computer‐aided design/computer‐assisted manufacturing (CAD/CAM) technologies were introduced in dentistry . The CAD/CAM workflow involves 3 fundamental steps: (1) data acquisition, (2) data processing, and (3) the manufacturing process …”

Section: Introductionmentioning

confidence: 99%

Laboratory workflow to obtain long‐term injected resin composite interim restorations from an additive manufactured esthetic diagnostic template

Piedra‐Cascón

Nuñez²,

Díez

et al. 2018

J Esthet Restor Dent

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“…The UV‐curable polymers are applied only where desired for the virtual design and, since multiple print nozzles can be used, the supporting material is co‐deposited. Moreover, different variations in color or building materials with different properties can be designated, including the formation or structures with spatially graded properties (Fig ) …”

Section: Materials Jetting (Mj Pp)mentioning

confidence: 99%

Additive Manufacturing Technologies Used for Processing Polymers: Current Status and Potential Application in Prosthetic Dentistry

Revilla‐León

Özcan

2018

Journal of Prosthodontics

361

301

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There are 7 categories of additive manufacturing (AM) technologies, and a wide variety of materials can be used to build a CAD 3D object. The present article reviews the main AM processes for polymers for dental applications: stereolithography (SLA), digital light processing (DLP), material jetting (MJ), and material extrusion (ME). The manufacturing process, accuracy, and precision of these methods will be reviewed, as well as their prosthodontic applications.

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“…The UV‐curable polymers are applied only where desired for the virtual design and, because multiple print nozzles can be used, the supporting material is co‐deposited. In addition, different variations in color or building material can be designated, including spatially graded structures (Figure ) …”

Section: Overviewmentioning

confidence: 99%

“…The digital workflow to manufacture a provisional restoration (Figure ) with a 3D printer consists of the following sequence: data acquisition, data processing, and manufacturing procedures Data acquisition involves digitization procedures normally performed by an extraoral or intraoral scanning device, in which the patient's mouth or the working casts are converted into a standard tessellation language (STL) file. Data processing involves the virtual design of the provisional restoration using specific CAD software.…”

Section: Manufacturing Workflowmentioning

confidence: 99%

A review on chemical composition, mechanical properties, and manufacturing work flow of additively manufactured current polymers for interim dental restorations

Revilla‐León

Meyers

Zandinejad

et al. 2018

J Esthet Restor Dent

137

109

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Objectives Additive manufacturing (AM) technologies can be used to fabricate 3D‐printed interim dental restorations. The aim of this review is to report the manufacturing workflow, its chemical composition, and the mechanical properties that may support their clinical application. Overview These new 3D‐printing provisional materials are typically composed of monomers based on acrylic esters or filled hybrid material. The most commonly used AM methods to manufacture dental provisional restorations are stereolithography (SLA) and material jetting (MJ) technologies. To the knowledge of the authors, there is no published article that analyzes the chemical composition of these new 3D‐printing materials. Because of protocol disparities, technology selected, and parameters of the printers and material used, it is notably difficult to compare mechanical properties results obtained in different studies. Conclusions Although there is a growing demand for these high‐tech restorations, additional information regarding the chemical composition and mechanical properties of these new provisional printed materials is required. Clinical Significance Additive manufacturing technologies are a current option to fabricate provisional dental restorations; however, there is very limited information regarding its chemical composition and mechanical properties that may support their clinical application.

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Novel polymeric support materials for jetting based additive manufacturing processes

Cited by 43 publications

References 30 publications

Laboratory workflow to obtain long‐term injected resin composite interim restorations from an additive manufactured esthetic diagnostic template

Laboratory workflow to obtain long‐term injected resin composite interim restorations from an additive manufactured esthetic diagnostic template

Additive Manufacturing Technologies Used for Processing Polymers: Current Status and Potential Application in Prosthetic Dentistry

A review on chemical composition, mechanical properties, and manufacturing work flow of additively manufactured current polymers for interim dental restorations

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