Digitalization Accuracy Clinical Trial
Official title:
Digitization Accuracy and Scannability of Two Different Implant-Supported Prosthodontic Framework Materials
The present study aims to clinically evaluate and compare the scanning accuracy and the scannability of 2 different materials used in constructing frameworks for implant-supported prosthesis (titanium and PEEK). The objective of the present study is to evaluate the digitization accuracy and scannability of milled titanium and PEEK implant-supported frameworks in intra-oral conditions and to evaluate the accuracy of the superstructures designed and constructed over the intraorally scanned framework.
Background: For implementing a fully digital workflow, intraoral scanning of prosthetic frameworks may be required for editing purposes in some clinical scenarios. Different materials can be used in constructing implant-supported prosthetic frameworks. However, the scannability and the influence of the material used on the accuracy of the intraoral scan are still unclear. Aim of the study: The purpose of this in vivo study is to evaluate the scanning accuracy and the scannability of different framework materials and to assess the marginal adaptation and accuracy of the superstructures designed and constructed over different scanned framework materials. Materials and methods: Two milled maxillary implant-supported frameworks constructed from 2 different materials will be used in this study. Group I will be constructed from titanium and group II from Poly-Ether-Ether-Ketone (PEEK). The frameworks will be digitized by using a desktop scanner (Tabletop Scanner, Medit T-310; Medit Corp). The STL file produced will be considered as a reference file. Each framework will be scanned intraorally (n=10) by using an intraoral scanner (IOS) (Medit i700; Medit Corp). The STL files obtained from the intraoral scanner will be compared to the reference STL file to assess the scannability. The unscanned surface area in a preset time limit will be used to determine the scannability of each framework. To evaluate the scanning accuracy, all STL files will be imported into a surface-matching software program (Medit Design v3.0.6 Build 286; Medit Corp) where deviation measurements in (μm) will be calculated. A total of 20 superstructures made of nano-ceramic hybrid resin (Flexcera™ Smile Ultra) will be 3D-printed from each STL file obtained from intraoral scanning of the frameworks and then the marginal adaptation will be evaluated by using a stereomicroscope (SZ1145TR; Olympus, Japan). The accuracy will also be assessed by using a surface-matching software program (Geomagic Control X v.2018.1.1; 3D Systems). Analysis: Data will be collected, tabulated, and statistically analyzed by using the appropriate statistical tests. Keywords: Digitization, accuracy, trueness, precision, scannability, implant-supported frameworks, superstructures, marginal adaptation, titanium, PEEK, digital workflow, editing, nano-ceramic hybrid resin. ;