The goal of this clinical trial is to evaluate and compare three digital workflows for the fabrication of definitive implant-supported full-arch prostheses in adult patients requiring fixed implant rehabilitation. The main questions it aims to answer are: * Does an automated AI-assisted digital workflow improve the passive fit of definitive full-arch implant-supported prostheses compared with manual and splint-guided alignment workflows? * Are there differences in marginal, geometric, mechanical, and radiographic passivity among the three digital workflows? Researchers will compare manual CBCT-STL alignment, splint-guided alignment, and automated AI-assisted CBCT-STL alignment to see if the degree of digital workflow automation affects the passive fit of definitive full-arch implant-supported prostheses. Participants will: * Be adults (18 years and older) indicated for fixed implant-supported full-arch rehabilitation. * Receive a definitive, screw-retained, full-arch implant-supported prosthesis fabricated using one of the three assigned digital workflows. * Undergo standardized clinical and radiographic assessments at the time of definitive prosthesis placement to evaluate prosthesis passive fit.
This randomized controlled clinical trial aims to evaluate and compare the passive fit of definitive full-arch implant-supported prostheses fabricated using three different digital workflows with increasing levels of automation for implant position registration and prosthesis fabrication. Full-arch implant-supported rehabilitations require a high level of precision to ensure passive fit between the prosthetic framework and the implant-abutment connections. Inadequate passive fit may lead to mechanical complications, biological overload, or long-term prosthetic failure. Digital workflows combining intraoral scanning (IOS) and cone-beam computed tomography (CBCT) have been introduced to improve accuracy; however, differences in data acquisition and dataset alignment strategies may influence the final prosthetic fit. The study will include adult patients (18 years and older) indicated for fixed implant-supported full-arch rehabilitation in the maxilla or mandible. Eligible participants will be recruited from the Faculty of Dentistry of the Complutense University of Madrid and associated clinical centers. After providing written informed consent, participants will be randomly assigned in a 1:1:1 ratio to one of three digital workflows: 1. Manual CBCT-STL alignment (MedicalFit 1.0): implant positions are obtained by combining intraoral scans and CBCT data, with dataset registration performed manually by the operator based on visual alignment of scan bodies. 2. Splint-guided alignment (MedicalFit 2.0): a calibrated rigid reference splint with metallic cylinders is used to stabilize implant positions and assist manual dataset registration, aiming to reduce operator-dependent variability. 3. Automated AI-assisted CBCT-STL alignment (MedicalFit 3.0 - Pdental): dataset registration and passivation are performed automatically by dedicated software using advanced algorithms for implant detection and alignment, without manual intervention. All participants will receive a definitive, screw-retained, full-arch implant-supported prosthesis fabricated according to the assigned digital workflow. Prosthetic materials and clinical procedures will follow standard clinical practice. No outcome measures will be assessed during provisional prosthetic phases. Passive fit will be evaluated exclusively at the time of definitive prosthesis placement using a standardized multi-assessment clinical approach performed at each implant-prosthesis connection. Marginal passive fit will be assessed clinically by direct inspection using a calibrated periodontal probe. The presence or absence of marginal discrepancies between the prosthesis and the transepithelial abutment will be evaluated based on visual and tactile criteria, including the ability of the probe to penetrate the prosthesis-abutment interface. Geometric passive fit will be evaluated using the modified Sheffield test. With all prosthetic screws loosened except for one distal screw, the presence of any lifting or separation of the prosthetic framework at the non-tightened connections will be assessed visually and tactually using an explorer probe. Mechanical passive fit will be assessed through the tactile sensitivity of the passive screw test. Resistance perceived during screw tightening will be evaluated qualitatively to identify the presence of internal stresses or framework flexure during seating of the definitive prosthesis. Radiographic passive fit will be assessed by measuring marginal gaps at the prosthesis-abutment interface on standardized periapical radiographs. Radiographic gaps will be quantified and classified using predefined ordinal thresholds to identify clinically relevant discrepancies. Each assessment will be scored using an ordinal scale (0-2) based on predefined clinical criteria. To reflect clinical decision-making and ensure a conservative interpretation of prosthetic fit, a hierarchical aggregation rule will be applied. For each assessment dimension, the prosthesis-level score will be defined as the worst score observed among all implant-prosthesis connections. The global multi-assessment passive fit score (0-2) will then be defined as the worst score observed across all assessment dimensions. Accordingly, if any implant-prosthesis connection exhibits a clinically relevant misfit in any assessment, the definitive prosthesis will be classified as non-passive. This approach reflects the clinical principle that lack of passive fit at a single connection compromises the overall prosthetic outcome. The primary objective of the study is to determine whether increased automation in digital workflows improves the passive fit of definitive full-arch implant-supported prostheses. Secondary objectives include comparing marginal, geometric, mechanical, and radiographic passivity outcomes among the three workflows and exploring the relationship between workflow automation and prosthetic adaptation accuracy. The study follows CONSORT guidelines and aims to provide clinically relevant evidence to support the optimization of digital workflows in full-arch implant-supported prosthetic rehabilitation
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
TREATMENT
Masking
SINGLE
Enrollment
30
This procedure consists of a fully digital workflow for fabricating a screw-retained, implant-supported full-arch prosthesis using manual alignment between CBCT and intraoral scan (STL) data. Scannable healing abutments (Tissue Shapers-IF; MedicalFit, Úbeda, Spain) are attached to multi-unit abutments torqued to 10 Ncm. A CBCT scan and an intraoral scan are acquired and manually aligned in CAD software using operator-defined reference points. Passive fit is adjusted manually during the CAD design stage. The definitive framework is milled from monolithic zirconia (IPS e.max ZirCAD Prime; Ivoclar, Schaan, Liechtenstein). This workflow is operator-dependent and serves as the control procedure.
This procedure employs a rigid reference splint with metallic abutment cylinders to guide dataset alignment for full-arch prosthesis fabrication. Scannable healing abutments (Tissue Shapers-IF; MedicalFit, Úbeda, Spain) are connected to multi-unit abutments torqued to 10 Ncm. The splint is attached intraorally and scanned extraorally to capture implant positions. The splint and intraoral scans (STL) are imported into CAD software, where manual alignment is performed using the splint as a reference. The final monolithic zirconia framework (IPS e.max ZirCAD Prime; Ivoclar, Schaan, Liechtenstein) is designed and milled via CAD/CAM. This workflow is operator-dependent and used as an active comparator.
This procedure uses AI-assisted software (Pdental, MedicalFit, Úbeda, Spain) to automate the alignment of CBCT and intraoral scan (STL) datasets for full-arch prosthesis fabrication. After placement of scannable healing abutments (Tissue Shapers-IF; MedicalFit), intraoral and CBCT scans are obtained. The software automatically detects healing abutments, performs CBCT-STL registration, and corrects deviations greater than 120 µm to achieve passive fit within clinically acceptable limits. The corrected digital model is exported in STL format for CAD design and CAM milling of a monolithic zirconia screw-retained prosthesis (IPS e.max ZirCAD Prime; Ivoclar, Schaan, Liechtenstein). This workflow minimizes operator dependency based on an AI-assisted automation. .
University Complutense of Madrid
Madrid, Madrid, Spain
RECRUITINGMulti-assessment global passive fit score of definitive full-arch implant-supported prostheses
Passive fit of the definitive full-arch implant-supported prosthesis will be evaluated using a standardized multi-assessment clinical approach. Marginal, geometric (modified Sheffield test), mechanical (passive screw test sensitivity), and radiographic passive fit will be assessed independently at each implant-prosthesis connection. Each assessment will be scored using an ordinal scale (0-2) based on predefined clinical criteria: 0 = no detectable discrepancy, indicating adequate passive fit; 1 = minor discrepancy, indicating a cl To obtain the prosthesis-level outcome, a conservative aggregation rule will be applied: for each assessment dimension, the prosthesis score will be defined as the worst score observed among all implant-prosthesis connections. The global multi-assessment passive fit score (0-2) will then be defined as the worst score observed across all assessment dimensions.
Time frame: At definitive prosthesis placement
Clinical marginal passive fit (probe assessment)
Marginal passive fit will be evaluated clinically by direct inspection using a calibrated probe to assess the presence of marginal discrepancies between the prosthesis and the transepithelial abutment. Outcomes will be recorded using an ordinal scale (0-2) based on visual and tactile criteria defined as follows: 0 = no visible gap and no probe penetration; 1. = visible marginal discrepancy without probe penetration; 2. = clinically detectable gap with probe penetration or visually, indicating lack of passive fit.
Time frame: At definitive prosthesis placement
Radiographic marginal gap at the prosthesis-abutment interface
Marginal gaps between the definitive prosthesis and the transepithelial abutment will be evaluated on standardized periapical radiographs. Measured gaps will be classified using an ordinal scale (0-2) as follows: 0 = gap \< 100 µm; 1. = gap between 100 and 130 µm; 2. = gap \> 130 µm, indicating a clinically relevant misfit.
Time frame: At definitive prosthesis placement
Geometric passive fit assessed by the modified Sheffield test
Geometric passive fit will be evaluated using the modified Sheffield test by tightening a single distal prosthetic screw and assessing the presence of lifting or separation at the non-tightened implant-prosthesis connections. Outcomes will be classified as follows: 0 = no visible or tactile separation; 1. = slight visible separation without probe penetration; 2. = clear separation with probe penetration, indicating absence of passive fit.
Time frame: At definitive prosthesis placement
Mechanical passive fit assessed by passive screw test sensitivity
Mechanical passive fit will be evaluated qualitatively based on tactile resistance perceived during tightening of the prosthetic screws. Outcomes will be classified using an ordinal scale (0-2) defined as follows: 0 = smooth screw tightening without perceptible resistance; 1. = mild or transient resistance without need for force; 2. = clear resistance or framework flexure during tightening, indicating internal stress and lack of passive fit.
Time frame: At definitive prosthesis placement
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