Accuracy Evaluation of Additively and Subtractively Fabricated Palatal Plate Orthodontic Appliances for Newborns and Infants–An In Vitro Study

Aretxabaleta, Maite; Unkovskiy, Alexey; Koos, Bernd; Spintzyk, Sebastian; Xepapadeas, Alexander B.

doi:10.3390/ma14154103

Cited by 14 publications

(17 citation statements)

References 31 publications

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“…The materials cost estimated in our exemplary case was 2 Euro for the presurgical plate and 3.5 Euro for the anatomical model. These piece costs were in the range of other groups using 3D printing in cleft care [ 26 ].…”

Section: Discussionmentioning

confidence: 89%

A Point-of-Care Digital Workflow for 3D Printed Passive Presurgical Orthopedic Plates in Cleft Care

Zarean

Thieringer

et al. 2022

Children

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Cleft lip and palate are one of the most common congenital craniofacial malformations. As an initial treatment, presurgical orthopedics is considered standard treatment at many cleft centers. Digital impressions are becoming feasible in cleft care. Computer-aided design (CAD) and three-dimensional (3D) printing are manufacturing standards in dentistry. The assimilation of these technologies has the potential to alter the traditional workflow for the fabrication of customized presurgical orthopedic plates. We present a digital workflow comprising three steps: 3D digital image acquisition with an intraoral scanner, open-source CAD modeling, and point-of-care 3D printing for the fabrication of personalized passive presurgical plates for newborns with cleft lip and palate. The digital workflow resulted in patient-related benefits, such as no risk of airway obstruction with quicker data acquisition (range 1–2.5 min). Throughput time was higher in the digital workflow 260–350 min compared to 135 min in the conventional workflow. The manual and personal intervention time was reduced from 135 min to 60 min. We show a clinically useful digital workflow for presurgical plates in cleft treatment. Once care providers overcome procurement costs, digital impressions, and point-of-care 3D printing will simplify these workflows and have the potential to become standard for cleft care.

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Section: Discussionmentioning

confidence: 89%

A Point-of-Care Digital Workflow for 3D Printed Passive Presurgical Orthopedic Plates in Cleft Care

Zarean

Thieringer

et al. 2022

Children

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“…Patients with gag reflects can be a problem, while scanning is most of the time the solution. Newborn cleft patients can be scanned using small scanner tips, thus avoiding the dangerous alginate impressions which can be only taken in a hospital environment, often under sedation or general anesthesia [ 34 ]. However, at this point in time, materials to directly print NAM plates do not exist, therefore, the traditional way of manufacturing NAM plates follows scanning, dental model 3D printing, and then NAM manufacture.…”

Section: Discussionmentioning

confidence: 99%

Three-Dimensional-Printed Customized Orthodontic and Pedodontic Appliances: A Critical Review of a New Era for Treatment

et al. 2022

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Three-dimensional (3D) designing and manufacturing technology is a direct derivative of digital technology. Three-dimensional volume and surface acquisition, CAD software, and 3D manufacturing are major changes included in daily practice in many orthodontic and pedodontic offices. Customized appliances can be designed using dental CAD software or general-purpose CAD software in the office or a laboratory. Materials that can be used are resins, alloys, or zirconia. Methods: The search strategy of this critical review included keywords in combination with MeSH terms in Medline, Scopus, and Cochrane Library up to June 2022 in the English language without any limit to the publication period. Results: According to our search, 12 articles were selected for our study. All the articles were in vitro prospective studies. Conclusions: The results suggested that almost all the known appliances can be designed and printed in a tailor-made fashion in contrast to the traditional one-size-fits-all approach. Customized appliances should be manufactured according to the patient’s needs, and this is justified by the certainty that this approach will be beneficial for the patient’s treatment. There is a need for more research on all direct 3D-printed appliances.

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“…In addition, previous studies on deviation analyses have also preferred the laboratory scanner used in the present study to generate master or test STL files. 7,[21][22][23][24] The rationale for using an IOS to digitize the MRM prior to DIM designs was to simulate a direct digital workflow. DIMs were fabricated by using a CLIPbased 3D printer, which is more laboratory-suited considering its cost.…”

Section: Discussionmentioning

confidence: 99%

“…20 A third-party SB (Elos Accurate Scan Body, IO 2B-B SA; Elos Medtech) was fixed to the implant analog with a screwdriver (Elos Accurate Screwdriver Manual Short 0.9 Hex; Elos Medtech, Göteborg, Sweden) and tightened with a torque wrench (Nobel Biocare Prosthetic Manual Torque Wrench; Nobel Biocare) at 5 Ncm. MRM was then digitized by using a laboratory scanner (3Shape D2000; 3Shape), 7,[21][22][23][24] which has an accuracy of 5 μm 25 to generate the standard tessellation language (STL) file of the MRM (M0). M0 file was used to fabricate custom impression trays for conventional closed-tray implant impressions.…”

Section: Methodsmentioning

confidence: 99%

Influence of digital implant analog design on the positional trueness of an analog in additively manufactured models: An in‐vitro study

Mata‐Mata¹,

Dönmez

Meirelles

et al. 2022

Clin Implant Dent Rel Res

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Background Limited evidence exists regarding the accuracy of implant analog position in printed models, particularly when implant analogs with varying designs are used. Purpose To evaluate the effect of digital implant analog (DIA) design on the trueness of their position in additively manufactured digital implant models (DIMs) and to compare with that of a conventional implant analog in a stone cast. Materials and Methods A dentate maxillary model with a conventional implant analog (Nobel Biocare Implant Replica 4.3 mm CC RP) at left second premolar site was digitized by using a laboratory scanner (3Shape D2000) and a (SB) scan body to generate the master standard tessellation language (STL) file (M0). 12 custom trays were fabricated on M0 file and conventional polyvinylsiloxane impressions of the model were made. All impressions were poured after inserting conventional implant analogs (Nobel RP Implant Replica) (Group A). Model was then digitized with an intraoral scanner (TRIOS 3) and the same SB, and DIMs with three different DIA designs (Nobel Biocare [Group B], Elos [Group C], and NT‐trading [Group D]) were generated (Dental System‐Model Builder). 12 DIMs of each design were additively manufactured and corresponding DIAs were inserted. All models were digitized by using the same laboratory scanner and SB, and these STLs were transferred to a 3D analysis software (Geomagic Control X), where the STL files of the models were superimposed over M0. Linear and 3D deviations at three selected points on SB (implant‐abutment connection, most cervical point on SB, and most coronal point on SB) as well as angular deviations on two planes (buccolingual and mesiodistal) were calculated. Analysis of variance (ANOVA) and Bonferroni corrected t‐tests were used to analyze the trueness of implant analog positions (α = 0.05). Results The interaction of main effects significantly affected linear (p < 0.001) and angular deviations (p = 0.020). At point 1, group D had higher deviations than groups A and B (p ≤ 0.015). In addition, groups A and D had higher deviations than group B at point 4 (p < 0.001). While group C had similar linear deviations to those of other groups at point 1 and point 4 (p ≥ 0.192), the differences among test groups at point 2 were nonsignificant (p ≥ 0.276). Group B had lower angular deviations than groups C (p = 0.039) and D (p = 0.006) on buccolingual plane. Conclusions Analog design affected the trueness of analog position as proprietary, pressure/friction fit DIA (group B) had higher linear trueness than screw‐retained DIA (Group D) and conventional implant analog (group A). In addition, pressure/friction fit DIA had the highest angular trueness among tested DIAs.

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Accuracy Evaluation of Additively and Subtractively Fabricated Palatal Plate Orthodontic Appliances for Newborns and Infants–An In Vitro Study

Cited by 14 publications

References 31 publications

A Point-of-Care Digital Workflow for 3D Printed Passive Presurgical Orthopedic Plates in Cleft Care

A Point-of-Care Digital Workflow for 3D Printed Passive Presurgical Orthopedic Plates in Cleft Care

Three-Dimensional-Printed Customized Orthodontic and Pedodontic Appliances: A Critical Review of a New Era for Treatment

Influence of digital implant analog design on the positional trueness of an analog in additively manufactured models: An in‐vitro study

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