Comparison of Accuracy of Maxilla Between Virtual and Conventional Surgical Planning in Bimaxillary Orthognathic Surgery
NCT ID: NCT06940024
Last Updated: 2025-04-23
Study Results
Results pending
The study team has not published outcome measurements, participant flow, or safety data for this trial yet. Check back later for updates.
Basic Information
Get a concise snapshot of the trial, including recruitment status, study phase, enrollment targets, and key timeline milestones.
Recruitment Status
ACTIVE_NOT_RECRUITING
Clinical Phase
NA
Total Enrollment
20 participants
Study Classification
INTERVENTIONAL
Study Start Date
2023-08-01
Study Completion Date
2025-07-31
Brief Summary
Review the sponsor-provided synopsis that highlights what the study is about and why it is being conducted.
Study Title Comparison of Maxillary Accuracy Between Virtual and Conventional Surgical Planning in Bimaxillary Orthognathic Surgery: A Randomized Controlled Trial Study Design
* Type: Prospective, single-center, randomized, blinded, case-controlled trial
* Location: National Hospital of Odonto-Stomatology, Ho Chi Minh City
* Period: August 2023 - February 2025
* Sample size: 20 patients
* Ethical approval: Granted by the University of Medicine and Pharmacy at HCMC (Approval No. 647/HĐĐĐ-ĐHYD) Inclusion Criteria
* Patients aged 18-30 years
* Diagnosed with malocclusion requiring bimaxillary orthognathic surgery
* Completed presurgical orthodontic treatment Exclusion Criteria
* Cleft lip/palate, craniofacial syndromes
* Deformities due to trauma, tumors, or iatrogenic causes
* TMJ disorders
* History of previous orthognathic surgery
* Planned multipiece Le Fort I osteotomy Randomization and Blinding
* All patients underwent both 2D and 3D surgical planning.
* Two splints (CSP and VSP) were fabricated for each patient.
* Intraoperative randomization was performed by an OR nurse.
* The surgical team and data analysts were blinded to group allocation.
* Groups were revealed only after data analysis. Groups
* Test group (VSP): 3D virtual planning, simulation, and 3D-printed splints
* Control group (CSP): 2D cephalometric planning, model surgery, conventional resin splints Surgical Procedure
* All patients underwent Le Fort I and BSSO
* Maxilla-first approach with fixation using 4 miniplates
* Mandibular repositioning using final splint and fixed with 2 miniplates per side
* All surgeries performed by a single experienced surgeon Data Collection \& Measurements
* CT scans before and 2 weeks after surgery
* Superimposition using Invivo 7.0 software (voxel-based registration)
* Measured landmark changes (A point, ANS, U1, U3, U6) in X (medial-lateral), Y (anterior-posterior), and Z (vertical) directions
* Compared:
* 2D plan (P2D) vs. 3D plan (P3D)
* P3D vs. actual postoperative result
* VSP vs. CSP accuracy Statistical Analysis
* ICC used to test measurement reliability (10 patients, remeasured after 2 weeks)
* Normality tested
* Paired t-test/Wilcoxon for planned vs. actual
* Independent t-test/Mann-Whitney for between-group comparisons
* Significance set at p \< 0.05
* Type: Prospective, single-center, randomized, blinded, case-controlled trial
* Location: National Hospital of Odonto-Stomatology, Ho Chi Minh City
* Period: August 2023 - February 2025
* Sample size: 20 patients
* Ethical approval: Granted by the University of Medicine and Pharmacy at HCMC (Approval No. 647/HĐĐĐ-ĐHYD) Inclusion Criteria
* Patients aged 18-30 years
* Diagnosed with malocclusion requiring bimaxillary orthognathic surgery
* Completed presurgical orthodontic treatment Exclusion Criteria
* Cleft lip/palate, craniofacial syndromes
* Deformities due to trauma, tumors, or iatrogenic causes
* TMJ disorders
* History of previous orthognathic surgery
* Planned multipiece Le Fort I osteotomy Randomization and Blinding
* All patients underwent both 2D and 3D surgical planning.
* Two splints (CSP and VSP) were fabricated for each patient.
* Intraoperative randomization was performed by an OR nurse.
* The surgical team and data analysts were blinded to group allocation.
* Groups were revealed only after data analysis. Groups
* Test group (VSP): 3D virtual planning, simulation, and 3D-printed splints
* Control group (CSP): 2D cephalometric planning, model surgery, conventional resin splints Surgical Procedure
* All patients underwent Le Fort I and BSSO
* Maxilla-first approach with fixation using 4 miniplates
* Mandibular repositioning using final splint and fixed with 2 miniplates per side
* All surgeries performed by a single experienced surgeon Data Collection \& Measurements
* CT scans before and 2 weeks after surgery
* Superimposition using Invivo 7.0 software (voxel-based registration)
* Measured landmark changes (A point, ANS, U1, U3, U6) in X (medial-lateral), Y (anterior-posterior), and Z (vertical) directions
* Compared:
* 2D plan (P2D) vs. 3D plan (P3D)
* P3D vs. actual postoperative result
* VSP vs. CSP accuracy Statistical Analysis
* ICC used to test measurement reliability (10 patients, remeasured after 2 weeks)
* Normality tested
* Paired t-test/Wilcoxon for planned vs. actual
* Independent t-test/Mann-Whitney for between-group comparisons
* Significance set at p \< 0.05
Related Clinical Trials
Explore similar clinical trials based on study characteristics and research focus.
Accuracy of Maxillary Fixation Using Custom Plates on Nasal Buttress Only Via Minimally Invasive Approach Versus Custom Plates on Nasal and Zygomatic Buttresses Via Conventional Approach in Orthognathic Surgeries
NCT07311785
Orthognathic Surgery
NOT_YET_RECRUITING
NA
Digital vs. Analog Inputs in CAD/CAM Orthodontics: A Comparative Clinical Evaluation of Palatal Expander Fabrication Workflow
NCT07338591
Transverse Maxillary Deficiency
NOT_YET_RECRUITING
Accuracy of Maxillary Repositioning With bi or Tripartite Disjonction by Virtual Planning in Orthognathic Surgery Using Patient-specific Titanium Plates
NCT05186376
Occlusal Trauma
COMPLETED
Personalized Titanium Plates vs CAD/CAM Surgical Splints in Maxillary Repositioning of Orthognathic Surgery
NCT02914431
Malocclusion
Abnormalities, Jaw
COMPLETED
NA
Comparison of Operating Room Time Length With the Use of Virtual Surgical Planning Versus Conventional Treatment of Mandible Fractures
NCT04283981
Mandibular Fractures
COMPLETED
NA
Detailed Description
Dive into the extended narrative that explains the scientific background, objectives, and procedures in greater depth.
Materials and Methods Study Design This study was conducted as a prospective, single-center, randomized, and blinded case-controlled trial. The research protocol was reviewed and approved by the Ethics Committee of the University of Medicine and Pharmacy at Ho Chi Minh City (Approval No. 647/HĐĐĐ-ĐHYD). All participants were fully informed of their treatment options and provided written informed consent prior to enrollment. The study adhered to ethical guidelines for clinical research, ensuring the protection of participants' rights, safety, and confidentiality.
Study Subjects The study was carried out at the National Hospital of Odonto-Stomatology in Ho Chi Minh City between August 2023 and February 2025. Eligible participants were aged 18 to 30 years and diagnosed with malocclusion requiring bimaxillary orthognathic surgery.
Exclusion criteria included:
1. Cleft lip and/or palate or craniofacial syndromes
2. Facial deformities resulting from trauma, tumors, or iatrogenic causes
3. Temporomandibular joint disorders
4. Previous history of orthognathic surgery
5. Indication for multipiece Le Fort I osteotomy A total of 20 patients met the inclusion criteria and agreed to participate. All patients had completed presurgical orthodontic treatment prior to surgery.
Randomization and Blinding Each patient underwent both two-dimensional (2D) lateral cephalometric analysis and three-dimensional (3D) virtual surgical planning preoperatively. For each case, both a conventional surgical splint and a 3D-printed splint were fabricated.
Randomization was performed intraoperatively by an operating room nurse through a simple draw to determine which splint would be used. Allocation was recorded accordingly. The surgical and research teams were blinded to group assignment, with participants identified only as "Group 1" or "Group 2." Group identities (VSP or CSP) were only disclosed after data collection and analysis were complete.
Patients were assigned to two groups:
* Test group (VSP): 3D imaging, virtual osteotomy simulations, and 3D-printed splints
* Control group (CSP): 3D imaging, virtual osteotomy simulations, model surgery, and hand-fabricated resin splints Methods Preoperative Examination and Surgical Planning All patients underwent a full preoperative assessment, including clinical examination, radiographic imaging (panoramic, lateral and posteroanterior cephalograms, and CT scans), 2D cephalometric analysis, intraoral and facial photography, and dental impressions.
Facebow registration and intermaxillary relationship assessment were performed, followed by mounting on a semi-adjustable articulator using the standard Frankfort horizontal plane. Final occlusion was determined by the orthodontist. Dental models were digitized using the Autoscan-DS-EX Pro (Shining 3D) scanner.
Surgical planning was initially based on clinical findings and 2D cephalometric analysis using WebCeph software. Parameters included maxillary dental midline, anteroposterior and vertical positioning of maxillary incisors, and occlusal plane canting determined by the canine and first molar reference points.
3D Simulation
A 3D virtual skull model was constructed using anatomical reference planes for consistent orientation:
* Horizontal plane: through Nasion, parallel to the Frankfort horizontal plane
* Midsagittal plane: through Nasion and Basion, perpendicular to the horizontal plane
* Coronal plane: through Nasion, perpendicular to both horizontal and midsagittal planes The mandible was repositioned into the final occlusion, and the maxillomandibular complex was aligned according to P2D (Planning 2D) parameters derived from 2D analysis. Maxillary landmarks (A point, ANS, U1, U1L, U1R, U3L, U3R, U6L, U6R) were recorded.
Next, refinements were applied using VSP to adjust occlusal plane canting, midline deviation, yaw rotation, and anteroposterior and vertical positioning based on Vietnamese normative standards. These refined landmark positions were recorded as P3D (Planning 3D).
Comparison Between P2D and P3D Differences in landmark movements between P2D and P3D (A point, ANS, U1, U1L, U1R, U3L, U3R, U6L, U6R) were analyzed to assess the discrepancies between 2D and 3D planning methods.
Group Allocation and Splint Fabrication
After determining the final maxillary and mandibular positions, surgical splints were fabricated as follows:
* CSP Group (Conventional Resin Occlusal Splint): Splints were manually fabricated based on P3D values. Landmarks were marked, and the maxillary model was segmented and repositioned to approximate the P3D position based on anterior-posterior and superior-inferior displacements. The actual repositioning distances of U1L, U1R, U3L, U3R, U6L, and U6R were recorded as PCM (Planning Cast Model).
* VSP Group (Virtual 3D-Printed Splint): Surgical splints were digitally generated using Dolphin software and printed using a Formlabs 3D printer.
Surgical Procedures All surgeries were performed by the same experienced maxillofacial surgeon using a standardized maxilla-first approach.
* Maxillary osteotomy was performed first (LeFort I), and the maxilla was positioned using the intermediate splint, with position verified by simulation images. Rigid fixation was performed using four miniplates and screws.
* Mandibular osteotomy followed (BSSO technique), and repositioning was guided by the final splint. Fixation was achieved with two miniplates per side.
* Final verification of skeletal alignment and occlusion was conducted before layered soft tissue closure.
* Intermaxillary fixation was not routinely used, but light elastics were applied as needed.
Postoperative Skeletal Accuracy Analysis Two weeks post-surgery, all patients underwent CT imaging in occlusion with the final splint and before initiation of postoperative orthodontic treatment.
Pre- and postoperative scans were superimposed using voxel-based registration (Invivo 7.0, Anatomage, CA), aligned to non-surgical cranial reference areas using the same reference planes:
* X-axis: medio-lateral (positive = left)
* Y-axis: antero-posterior (positive = forward)
* Z-axis: superior-inferior (positive = downward) Landmark movements (A point, ANS, U1, U1L, U1R, U3L, U3R, U6L, U6R) were recorded as Actual values.
Surgical accuracy was evaluated through:
* Intra-group comparisons: P3D vs. Actual positions for each landmark
* Inter-group comparisons: Discrepancies between VSP and CSP groups Measurement Methods for Accuracy Assessment The intraclass correlation coefficient (ICC) was used to assess measurement reliability. Ten patients were randomly selected and remeasured after two weeks.
Statistical Analysis
* Normality testing was performed for all variables.
* If normally distributed, paired t-tests were used for P3D vs. Actual, and independent t-tests for CSP vs. VSP comparisons.
* If non-normally distributed, Wilcoxon signed-rank and Mann-Whitney U tests were applied.
* A p-value of \< 0.05 was considered statistically significant.
Study Subjects The study was carried out at the National Hospital of Odonto-Stomatology in Ho Chi Minh City between August 2023 and February 2025. Eligible participants were aged 18 to 30 years and diagnosed with malocclusion requiring bimaxillary orthognathic surgery.
Exclusion criteria included:
1. Cleft lip and/or palate or craniofacial syndromes
2. Facial deformities resulting from trauma, tumors, or iatrogenic causes
3. Temporomandibular joint disorders
4. Previous history of orthognathic surgery
5. Indication for multipiece Le Fort I osteotomy A total of 20 patients met the inclusion criteria and agreed to participate. All patients had completed presurgical orthodontic treatment prior to surgery.
Randomization and Blinding Each patient underwent both two-dimensional (2D) lateral cephalometric analysis and three-dimensional (3D) virtual surgical planning preoperatively. For each case, both a conventional surgical splint and a 3D-printed splint were fabricated.
Randomization was performed intraoperatively by an operating room nurse through a simple draw to determine which splint would be used. Allocation was recorded accordingly. The surgical and research teams were blinded to group assignment, with participants identified only as "Group 1" or "Group 2." Group identities (VSP or CSP) were only disclosed after data collection and analysis were complete.
Patients were assigned to two groups:
* Test group (VSP): 3D imaging, virtual osteotomy simulations, and 3D-printed splints
* Control group (CSP): 3D imaging, virtual osteotomy simulations, model surgery, and hand-fabricated resin splints Methods Preoperative Examination and Surgical Planning All patients underwent a full preoperative assessment, including clinical examination, radiographic imaging (panoramic, lateral and posteroanterior cephalograms, and CT scans), 2D cephalometric analysis, intraoral and facial photography, and dental impressions.
Facebow registration and intermaxillary relationship assessment were performed, followed by mounting on a semi-adjustable articulator using the standard Frankfort horizontal plane. Final occlusion was determined by the orthodontist. Dental models were digitized using the Autoscan-DS-EX Pro (Shining 3D) scanner.
Surgical planning was initially based on clinical findings and 2D cephalometric analysis using WebCeph software. Parameters included maxillary dental midline, anteroposterior and vertical positioning of maxillary incisors, and occlusal plane canting determined by the canine and first molar reference points.
3D Simulation
A 3D virtual skull model was constructed using anatomical reference planes for consistent orientation:
* Horizontal plane: through Nasion, parallel to the Frankfort horizontal plane
* Midsagittal plane: through Nasion and Basion, perpendicular to the horizontal plane
* Coronal plane: through Nasion, perpendicular to both horizontal and midsagittal planes The mandible was repositioned into the final occlusion, and the maxillomandibular complex was aligned according to P2D (Planning 2D) parameters derived from 2D analysis. Maxillary landmarks (A point, ANS, U1, U1L, U1R, U3L, U3R, U6L, U6R) were recorded.
Next, refinements were applied using VSP to adjust occlusal plane canting, midline deviation, yaw rotation, and anteroposterior and vertical positioning based on Vietnamese normative standards. These refined landmark positions were recorded as P3D (Planning 3D).
Comparison Between P2D and P3D Differences in landmark movements between P2D and P3D (A point, ANS, U1, U1L, U1R, U3L, U3R, U6L, U6R) were analyzed to assess the discrepancies between 2D and 3D planning methods.
Group Allocation and Splint Fabrication
After determining the final maxillary and mandibular positions, surgical splints were fabricated as follows:
* CSP Group (Conventional Resin Occlusal Splint): Splints were manually fabricated based on P3D values. Landmarks were marked, and the maxillary model was segmented and repositioned to approximate the P3D position based on anterior-posterior and superior-inferior displacements. The actual repositioning distances of U1L, U1R, U3L, U3R, U6L, and U6R were recorded as PCM (Planning Cast Model).
* VSP Group (Virtual 3D-Printed Splint): Surgical splints were digitally generated using Dolphin software and printed using a Formlabs 3D printer.
Surgical Procedures All surgeries were performed by the same experienced maxillofacial surgeon using a standardized maxilla-first approach.
* Maxillary osteotomy was performed first (LeFort I), and the maxilla was positioned using the intermediate splint, with position verified by simulation images. Rigid fixation was performed using four miniplates and screws.
* Mandibular osteotomy followed (BSSO technique), and repositioning was guided by the final splint. Fixation was achieved with two miniplates per side.
* Final verification of skeletal alignment and occlusion was conducted before layered soft tissue closure.
* Intermaxillary fixation was not routinely used, but light elastics were applied as needed.
Postoperative Skeletal Accuracy Analysis Two weeks post-surgery, all patients underwent CT imaging in occlusion with the final splint and before initiation of postoperative orthodontic treatment.
Pre- and postoperative scans were superimposed using voxel-based registration (Invivo 7.0, Anatomage, CA), aligned to non-surgical cranial reference areas using the same reference planes:
* X-axis: medio-lateral (positive = left)
* Y-axis: antero-posterior (positive = forward)
* Z-axis: superior-inferior (positive = downward) Landmark movements (A point, ANS, U1, U1L, U1R, U3L, U3R, U6L, U6R) were recorded as Actual values.
Surgical accuracy was evaluated through:
* Intra-group comparisons: P3D vs. Actual positions for each landmark
* Inter-group comparisons: Discrepancies between VSP and CSP groups Measurement Methods for Accuracy Assessment The intraclass correlation coefficient (ICC) was used to assess measurement reliability. Ten patients were randomly selected and remeasured after two weeks.
Statistical Analysis
* Normality testing was performed for all variables.
* If normally distributed, paired t-tests were used for P3D vs. Actual, and independent t-tests for CSP vs. VSP comparisons.
* If non-normally distributed, Wilcoxon signed-rank and Mann-Whitney U tests were applied.
* A p-value of \< 0.05 was considered statistically significant.
Conditions
See the medical conditions and disease areas that this research is targeting or investigating.
Orthognathic Surgical Procedures
3D Printing
Splints
Study Design
Understand how the trial is structured, including allocation methods, masking strategies, primary purpose, and other design elements.
Allocation Method
RANDOMIZED
Intervention Model
PARALLEL
After determining the desired the maxillary and mandibular position by 3D planning, involved fabricating surgical splints using two different methods:
* CSP Group (Conventional Resin Occlusal Splint - Control group): Splints were manually fabricated based on P3D movement values. Maxillary landmark points were marked, and the upper jaw cast model was segmented and repositioned to match P3D maxillary to the nearest approximation base on anterior-posterior and superior-inferior changes of these points. The actual movement distances of U1L, U1R, U3L, U3R, U6L, and U6R were recorded as PCM (Planning Cast Model).
* VSP Group (Virtual Digital Occlusal 3D Print Splint - Interventional group): Digital surgical splints were generated using Dolphin software and a Form 3D printer.
* CSP Group (Conventional Resin Occlusal Splint - Control group): Splints were manually fabricated based on P3D movement values. Maxillary landmark points were marked, and the upper jaw cast model was segmented and repositioned to match P3D maxillary to the nearest approximation base on anterior-posterior and superior-inferior changes of these points. The actual movement distances of U1L, U1R, U3L, U3R, U6L, and U6R were recorded as PCM (Planning Cast Model).
* VSP Group (Virtual Digital Occlusal 3D Print Splint - Interventional group): Digital surgical splints were generated using Dolphin software and a Form 3D printer.
Primary Study Purpose
TREATMENT
Blinding Strategy
TRIPLE
Participants
Investigators
Outcome Assessors
Study Groups
Review each arm or cohort in the study, along with the interventions and objectives associated with them.
CSP Group (Conventional Resin Occlusal Splint)
Splints were manually fabricated based on 3D planning movement values
Group Type
NO_INTERVENTION
No interventions assigned to this group
VSP Group
Digital surgical splints were generated using Dolphin software and a Form 3D printer
Group Type
EXPERIMENTAL
VSP Group
Intervention Type
DEVICE
Digital surgical splints were generated using Dolphin software and a Form 3D printer
Interventions
Learn about the drugs, procedures, or behavioral strategies being tested and how they are applied within this trial.
VSP Group
Digital surgical splints were generated using Dolphin software and a Form 3D printer
Intervention Type
DEVICE
Eligibility Criteria
Check the participation requirements, including inclusion and exclusion rules, age limits, and whether healthy volunteers are accepted.
Inclusion Criteria
* Patients with malocclusion requiring orthognathic surgery
Exclusion Criteria
* cleft lip and palate congenital abnormalities
* the facial deformities were caused by trauma, tumor, or iatrogenic factors
* temporomandibular joint disorders
* history of previous orthognathic surgery
* patients scheduled for multipiece Le Fort I osteotomy
* the facial deformities were caused by trauma, tumor, or iatrogenic factors
* temporomandibular joint disorders
* history of previous orthognathic surgery
* patients scheduled for multipiece Le Fort I osteotomy
Minimum Eligible Age
18 Years
Maximum Eligible Age
30 Years
Eligible Sex
ALL
Accepts Healthy Volunteers
No
Sponsors
Meet the organizations funding or collaborating on the study and learn about their roles.
University of Medicine and Pharmacy at Ho Chi Minh City
OTHER
Sponsor Role
lead
Responsible Party
Identify the individual or organization who holds primary responsibility for the study information submitted to regulators.
Nguyen Phuoc Loi
Principal Investigator, Lecturer of Maxillofacial Surgery Department
Responsibility Role
PRINCIPAL_INVESTIGATOR
Locations
Explore where the study is taking place and check the recruitment status at each participating site.
201A, Nguyen Chi Thanh Street
Ho Chi Minh City, Ho Chi Minh, Vietnam
Site Status
Countries
Review the countries where the study has at least one active or historical site.
Vietnam
References
Explore related publications, articles, or registry entries linked to this study.
Chen H, Bi R, Hu Z, Chen J, Jiang N, Wu G, Li Y, Luo E, Zhu S. Comparison of three different types of splints and templates for maxilla repositioning in bimaxillary orthognathic surgery: a randomized controlled trial. Int J Oral Maxillofac Surg. 2021 May;50(5):635-642. doi: 10.1016/j.ijom.2020.09.023. Epub 2020 Oct 31.
Reference Type
BACKGROUND
Schneider D, Kammerer PW, Hennig M, Schon G, Thiem DGE, Bschorer R. Customized virtual surgical planning in bimaxillary orthognathic surgery: a prospective randomized trial. Clin Oral Investig. 2019 Jul;23(7):3115-3122. doi: 10.1007/s00784-018-2732-3. Epub 2018 Nov 15.
Reference Type
BACKGROUND
Ritto FG, Schmitt ARM, Pimentel T, Canellas JV, Medeiros PJ. Comparison of the accuracy of maxillary position between conventional model surgery and virtual surgical planning. Int J Oral Maxillofac Surg. 2018 Feb;47(2):160-166. doi: 10.1016/j.ijom.2017.08.012. Epub 2017 Sep 23.
Reference Type
BACKGROUND
Song KG, Baek SH. Comparison of the accuracy of the three-dimensional virtual method and the conventional manual method for model surgery and intermediate wafer fabrication. Oral Surg Oral Med Oral Pathol Oral Radiol Endod. 2009 Jan;107(1):13-21. doi: 10.1016/j.tripleo.2008.06.002. Epub 2008 Aug 28.
Reference Type
BACKGROUND
Xu R, Ye N, Zhu S, Shi B, Li J, Lai W. Comparison of the postoperative and follow-up accuracy of articulator model surgery and virtual surgical planning in skeletal class III patients. Br J Oral Maxillofac Surg. 2020 Oct;58(8):933-939. doi: 10.1016/j.bjoms.2020.04.032. Epub 2020 May 20.
Reference Type
BACKGROUND
Other Identifiers
Review additional registry numbers or institutional identifiers associated with this trial.
647/HĐĐĐ-ĐHYD
Identifier Type: -
Identifier Source: org_study_id
More Related Trials
Additional clinical trials that may be relevant based on similarity analysis.
Assessment of Maxillary Stability in Bimaxillary Orthognathic Patients Using the Inverted Sequence Approach
NCT03353116
COMPLETED
NA
The Evaluation Of The Efficiency Of Micro-osteoperforation
NCT03652454
COMPLETED
NA
"Three Dimensional Assessment of Maxillary Molars Following Distalization Using Two Different Approaches"
NCT06240923
COMPLETED
NA
Micro-Osteoperforations to Accelerate Maxillary Canine Retraction in Class I Malocclusion
NCT07155018
COMPLETED
NA
Impact of 3D-Printed Anatomical Model on Patient Understanding in Orthognathic Surgery
NCT07068412
RECRUITING
NA
Conventional vs Digital CAD/CAM Splints for Bruxism
NCT06518447
COMPLETED
NA
Assessment of the Efficacy of Microosteoperforations Versus Injectable Platelet-rich Fibrin During Orthodontic Leveling and Alignment of Mandibular Incisors
NCT06498609
ENROLLING_BY_INVITATION
NA
Three-Dimensional Assessment of Maxillary Canine Retraction With and Without Power Arm
NCT06352996
ACTIVE_NOT_RECRUITING
NA
Facial Conformation Meshes for Orthognathic Surgery
NCT06893614
RECRUITING
Accuracy of Patient Specific 3D Printed Titanium Plates Versus Milled Titanium Plates in Genioplasty Orthognathic Surgeries.
NCT07344441
NOT_YET_RECRUITING
NA
Evaluating the Efficacy of Micro-Osteoperforations Technique on the Orthodontic Tooth Movement Acceleration in Moderate Mandibular Anterior Crowding Cases Treated With Clear Aligners
NCT05492773
RECRUITING
NA
Custom Titanium Plates vs. 3D Splints in LeFort I Osteotomy
NCT06933628
COMPLETED
NA
Evaluation of the Effectiveness of Piezocision and Micro-osteoperforation in Alleviating Mandibular Anterior Crowding
NCT04940351
UNKNOWN
NA
3D Printed vs. Milled Occlusal Splints in Dentistry
NCT07236294
NOT_YET_RECRUITING
Assessment of the Accuracy of Patient Specific Plates for Correction of Maxillary Cant in Facial Asymmetry
NCT07001826
RECRUITING
NA
Evaluation of Segmented Versus Full Arch Three Dimensionally Printed Transfer Tray for Orthodontic Indirect Bonding
NCT03564717
UNKNOWN
NA
The Rate of Space Closure With Piezocision-based Corticotomy in Different Facial Types: A Split-mouth Design
NCT04202016
COMPLETED
NA
Impact of Retro-molar Pad Demarcation on Complete Denture Wearers' Satisfaction
NCT07246343
COMPLETED
NA
Acceleration of Alignment of Crowded Lower Anterior Teeth
NCT03659097
COMPLETED
NA
3D Printed Models in 3D Virtual Treatment Planning of Orthognathic Surgery
NCT03986723
COMPLETED
Evaluation of the Root Resorption and Dehiscence Formation Between Two Methods of Leveling and Alignment of Lower Teeth
NCT04601662
COMPLETED
NA
Effectiveness of Auxiliary Segmental Lingual Appliances in Leveling the Curve of Wilson at Second Molars
NCT06858670
RECRUITING
NA
Evaluation of Leveling and Alignment of Maxillary Anterior Teeth Assisted With MOPs :A Comparative Clinical Study
NCT05605652
UNKNOWN
NA
Effects of Mini Implant Facilitated Micro-osteoperforations on the Alignment of Mandibular Anterior Crowding
NCT04778241
COMPLETED
NA
Indirect Bonding Accuracy of 3D Printed Digital Transfer Trays
NCT06167278
RECRUITING
NA