Get your knowledge up-to-date with the most complete blended Master's Degree in Digital Dentistry in the current academic panorama”

From intraoral scanning, digital radiography, Augmented Reality to VR have been introduced in the dental sector, completely transforming diagnostic and therapeutic procedures. In this regard, in recent years, there has been a major drive to improve assessment and intervention techniques, reducing errors due to human factors.

In this scenario of digitization and continuous evolution, it is necessary for dentists to be up to date and provide the most advanced therapy to their patients. For this reason, TECH has created this 12-month Hybrid professional master’s degree in Digital Dentistry.

This is a very complete program that leads the graduate to deepen in design software both open and closed source, in the digital flow used for the planning of invisible orthodontics, Guided Surgery or in the preparation of minimally invasive interventions. High-quality teaching material (video summaries, detailed videos), scientific readings and case studies are available for this purpose.

But, undoubtedly, in this program, the stay in a state-of-the-art clinic makes the difference. In this first class space, the graduate will have the opportunity to be involved in the most advanced methodologies and the most advanced digital equipment for the care of the main pathologies.

A unique academic experience, where you will have at your fingertips the most rigorous syllabus created by real specialists and, subsequently, where you will be guided by active experts with extensive experience in this sector.

High quality multimedia material, access is available 24 hours a day, 7 days a week”

This Hybrid professional master’s degree in Digital Dentistry contains the most complete and up-to-date scientific program on the market. The most important features include:

• Development of more than 100 clinical cases presented by nursing professionals
• The graphic, schematic, and practical contents with which they are created, provide scientific and practical information on the disciplines that are essential for professional practice
• Patient assessment using the most advanced software in Digital Dentistry
• Comprehensive systematized action plans for the main pathologies in Current Pediatric
• Presentation of diagnostic and therapeutic techniques using the latest technology
• An algorithm-based interactive learning system for decision-making in the clinical situations presented throughout the course
• With a special emphasis on evidence-based medicine and research methodologies in Digital Dentistry
• All of this will be complemented by theoretical lessons, questions to the expert, debate forums on controversial topics, and individual reflection assignments
• Content that is accessible from any fixed or portable device with an Internet connection
• Furthermore, you will be able to carry out a clinical internship in one of the best Clinic centers

Get a complete up-to-date through this degree that gives you 3 weeks of practical training, surrounded by the best dental experts”

In this proposal for a Master's Degree, of a professionalizing nature and blended learning modality, the program is aimed at updating Dentist who perform their functions in clinical centers and hospitals, Spaces who require a high level of qualification. The content is based on the latest scientific evidence and is organized in a didactic way to integrate theoretical knowledge into dentistry practice. The theoretical-practical elements allow professionals to bringing their knowledge up-to-date and help them to make the right decisions in patient care.

Thanks to its multimedia content developed with the latest educational technology, they will allow the professional to learn in a contextual and situated learning environment, i.e., a simulated environment that will provide immersive learning programmed to train in real situations. This program is designed around Problem-Based Learning, whereby the physician must try to solve the different professional practice situations that arise during the course. For this purpose, the students will be assisted by an innovative interactive video system created by renowned and experienced experts.

This Hybrid professional master’s degree allows you to be up to date with the digital tools used for occlusion"

From a theoretical-practical perspective, you will delve in the planning and design of Endodontics and Periodontics"

The study program of this university degree brings together over 12 months, the latest information on the most advanced techniques, software and procedures used in Digital Dentistry. Therefore, thanks to this academic course, the graduate will obtain an advanced theoretical framework of great practical application. For that, An extensive library of multimedia resources, is available 24 hours a day, 7 days a week. A process that will culminate in a stay that will lead to a complete up-to-date and direct use in the best dental clinics.

You will have at your fingertips a study plan, complemented by numerous multimedia didactic material”

Module 1. Equipment digitization

1.1. Video evolution

1.1.1. Why you should go digital
1.1.2. Multidisciplinary
1.1.3. Time/expenditure
1.1.4. Advantages/costs

1.2. Digital Flow

1.2.1. File types
1.2.2. Types of meshes
1.2.3. Reliability
1.2.4. Comparison of systems

1.3. Digital camera and digital mobile

1.3.1. in dentistry Lighting Techniques
1.3.2. Clinical Analysis Dental Photography
1.3.3. Aesthetic dental photography techniques
1.3.4. Image Editing

1.4. Digital Radiology

1.4.1. Types of X-Rays:
1.4.2. Digital radiology technology
1.4.3. Taking digital dental radiographs
1.4.4. AI interpretation of dental radiographs

1.5. CBCT

1.5.1. CBCT technology
1.5.2. interpretation of CBCT images
1.5.3. Diagnostic CBCT imaging
1.5.3. CBCT applications in implantology
1.5.4. CBCT applications in Endodontics

1.6. Dental scanner

1.6.1. Dentition and Soft Tissue Scanning
1.6.2. Digital modeling in dentistry
1.6.3. Design and fabrication of digital dental prostheses
1.6.4. Applications of dental scanners in orthodontics

1.7. Dynamic stereoscopy

1.7.1. Dynamic stereoscopic imaging
1.7.2. Dynamic stereoscopic image interpretation
1.7.3. Integration of dynamic stereoscopy into the dental workflow
1.7.4. Ethics and safety in the use of dynamic stereoscopy

1.8. PIC Photogranulometry

1.8.1. PIC phonogranulometry technology
1.8.2. Interpretation of phonogranulometric records PIC
1.8.3. Applications of PIC phonogranulometry in dental occlusion
1.8.4. Advantages and Disadvantages of the PIC Technique

1.9. Facial scanner

1.9.1. Facial scanner recording
1.9.2. Data Analysis and Assessment Facial
1.9.3. Integration of dynamic stereoscopy into the dental workflow
1.9.4. Future of facial scanning in dentistry

1.10. Files

1.10.1. Types of digital files in dentistry
1.10.2. Digital File Formats
1.10.3. Archive Storage and Management
1.10.4. Digital file security and privacy

Module 2. Cephalometric analysis and photography

2.1. Principles of Photography

2.1.1. The NO Digital Image
2.1.2. The Digital Image
2.1.3. The detail
2.1.4. Advice

2.2. The Photography in the Science

2.2.1. Uses of Photography
2.2.2. Case documentation
2.2.3. Hospital photography
2.2.4. Social media

2.3. The Photography in the Current Pediatric

2.3.1. Photography in orthodontics
2.3.2. Photography in Implantology
2.3.3. Photography in Periodontics
2.3.4. Photography in dental esthetics

2.4. Purposes of dental photography

2.4.1. Pharmacist-Patient Communication
2.4.2. Laboratory communication
2.4.3. Legal communication
2.4.4. Artistic

2.5. The Photographic Camera

2.5.1. Types of Cameras
2.5.2. Camera Parts
2.5.3. Phone camera
2.5.4. Lenses

2.6. Camera Usability

2.6.1. Flashes
2.6.2. Controlling Light
2.6.3. Exhibition
2.6.4. A Learning Curve

2.7. Management of Photography

2.7.1. Diaphragm
2.7.2. Speed
2.7.3. Focus
2.7.4. Match

2.8. Digital development, storage and design

2.8.1. Image storage
2.8.2. Formats
2.8.3. Digital Development
2.8.4. Program Design

2.9. BSB digital cephalometry

2.9.1. Fundamentals of digital cephalometry in dentistry
2.9.2. Scanning technologies in digital cephalometry
2.9.3. Interpretation of digital cephalometric data
2.9.4. Clinical applications of digital cephalometry

2.10. Digital cephalometry programs (Ortokid)

2.10.1. Program installation
2.10.2. Patient discharge
2.10.3. Placement of reference points
2.10.4. Study selection

Module 3. Closed-source design software

3.1. Design with Exocad

3.1.1. Data upload
3.1.2. Work order
3.1.3. CAD design, file import
3.1.4. CAD design, design tools

3.2. Exocad design of temporary crowns

3.2.1. Work order
3.2.2. Selection of Materials
3.2.3. Crown design
3.2.4. File export

3.3. Exocad bridge design

3.3.1. Work order
3.3.2. Selection of Materials
3.3.3. Bridge design
3.3.4. File export

3.4. Exocad Inlays design

3.4.1. Work order
3.4.2. Selection of Materials
3.4.3. Inlay design
3.4.4. File export

3.5. Exocad design of on Implants crowns

3.5.1. Work order
3.5.2. Selection of Materials
3.5.3. Crown design on implants
3.5.4. File export

3.6. Blender design of Geller models

3.6.1. File Import
3.6.2. Geller Model Design
3.6.3. Geller Model Data Science
3.6.4. Geller Model Fabrication

3.7. Blender design of discharge cell design

3.7.1. File Import
3.7.2. Business Model Design
3.7.3. Geller Model Data Science
3.7.4. Geller Model Fabrication

3.8. Blender design of Occlusal

3.8.1. File Import
3.8.2. Geller Model Design
3.8.3. Geller Model Data Science
3.8.4. Geller Model Fabrication

3.9. Blender design of Occlusal

3.9.1. Blender software functions and tools for occlusal mapping
3.9.2. Occlusal map
3.9.3. Occlusal map interpretation
3.9.4. Occlusal map Analysis

3.10. Design with Blender for 3D printing model preparation

3.10.1. Data Science
3.10.2. Model selection
3.10.3. Digital model repair
3.10.4. Model labeling and export

Module 4. Open-Source design software

4.1. Mesh Meshmixer design

4.1.1. Meshmixer software functions and tools on meshes
4.1.2. Mesh Import
4.1.3. Mesh repair
4.1.4. Model printing

4.2. Mirror copy Meshmixer design

4.2.1. Meshmixer software functions and tools Copies on mirror
4.2.2. Tooth design
4.2.3. Model export
4.2.4. Mesh adjustment

4.3. Temporary screw-in Meshmixer design

4.3.1. Functions and tools of the Meshmixer software in screw-in
4.3.2. Screw-in design
4.3.3. Screw-in manufacturing
4.3.4. Screw-in Adjustment and placement

4.4. Meshmixer design with provisional eggshell

4.4.1. Eggshell Meshmixer software functions and tools
4.4.2. Eggshell design
4.4.3. Eggshell manufacturing
4.4.4. Eggshell adjustment and placement

4.5. Libraries

4.5.1. Import of libraries
4.5.2. Different uses
4.5.3. Autosave
4.5.4. Data recovery

4.6. Design with BSB of tooth-supported splints

4.6.1. Basis of use
4.6.2. Types
4.6.3. Guided Surgery Systems
4.6.4. Fabrication

4.7. Crown and bridge design

4.7.1. File Import
4.7.2. Crown design
4.7.3. Bridge design
4.7.4. File export

4.8. Denture

4.8.1. File Import
4.8.2. Denture design
4.8.3. Tooth design
4.8.4. File export

4.9. Model editing

4.9.1. BSB software functions and tools for Immediate Implant
4.9.2. Immediate implant design
4.9.3. Immediate implant Fabrication
4.9.4. Immediate implant fitting and placement

4.10. Chairside Splints

4.10.1. BSB software functions and tools for surgical
4.10.2. Surgical splint design
4.10.3. Surgical splint Fabrication
4.10.4. Surgical splint fitting and placement

Module 5. Digital Flow and Invisible Orthodontics. Planning & Software

5.1. Different software available for creating

5.1.1. Open-ource
5.1.2. BSB
5.1.3. Closed-Source
5.1.4. Teacher

5.2. Nemocast

5.2.1. Import, orientation
5.2.2. Top and bottom model segmentation
5.2.3. Setup and placement of attachments
5.2.4. Stl Export

5.3. Blue Sky Bio

5.3.1. Import, orientation
5.3.2. Top and bottom model segmentation
5.3.3. Setup and placement of attachments
5.3.4. Stl Export

5.4. Teacher

5.4.1. Import, orientation
5.4.2. Top and bottom model segmentation
5.4.3. Setup and placement of attachments
5.4.4. Stl Export

5.5. Study Models

5.5.1. Types of Studies Models
5.5.2. Advantages and Disadvantages of the digital study Model
5.5.3. Process of scanning physical study models
5.5.4. Process of creation Digital study models

5.6. Template placement for brackets

5.6.1. What is a bracket template?
5.6.2. Design
5.6.3. Materials Used
5.6.4. Adjustments

5.7. Masks and positioning guides for cofferdams

5.7.1. What are attachments in invisible orthodontics?
5.7.2. Masks and positioning guides for cofferdams?
5.7.3. Design and manufacturing process for masks and positioning guides for cofferdam attachments
5.7.4. Masks and positioning guides for cofferdams

5.8. Different brands of invisible aligners

5.8.1. Invisaline
5.8.2. Spark
5.8.3. Smilers
5.8.4. Clear Correct

5.9. Digital Mockup

5.9.1. Concept and application of Digital Mockup in invisible orthodontics
5.9.2. Workflow for the creation of a Digital Mockup
5.9.3. Use of digital tools for case planning in invisible orthodontics
5.9.4. Analysis of clinical cases and examples of the application of Digital Mockup

5.10. Mouth scanning

5.10.1. Upper Jaw 3D
5.10.2. Lower Jaw
5.10.3. Bites
5.10.4. Revision of the Model

Module 6. Digital Flow and Aesthetic Planning. DSD

6.1. DSD

6.1.1. Proportions 2 D
6.1.2. Proportions 3 D
6.1.3. Aesthetic planning
6.1.4. File export

6.2. Software

6.2.1. DSD1
6.2.2. Design export
6.2.3. Aesthetic planning
6.2.4. File export

6.3. Design

6.3.1. Virtual simulation of treatments and its importance in esthetic planning
6.3.2. Designing esthetic dental restorations using digital design
6.3.3. Tooth preparation techniques for the design of esthetic dental restorations
6.3.4. Cementing and bonding techniques for esthetic dental restorations

6.4. Proportions

6.4.1. Dental and facial anatomy applied to the analysis of proportions
6.4.2. Ideal dental and facial proportions in the smile and their relationship to facial aesthetics
6.4.3. Importance of ratio analysis in implant dentistry treatment planning
6.4.4. Integration of proportion analysis into the patient's overall esthetic planning

6.5. Mockup fabrication

6.5.1. Use of mockup in aesthetic treatment planning
6.5.2. Use of mockup in implant dentistry treatment planning
6.5.3. Use of mockup for smile design presentation to the patient and interdisciplinary communication
6.5.4. Integration of the digital flow in the manufacture of mockups

6.6. Color Acquisition

6.6.1. Data Science
6.6.2. Heat Map
6.6.3. Laboratory communication
6.6.4. Communication with Patient

6.7. Vitamin

6.7.1. Equipment
6.7.2. Color Acquisition Zones
6.7.3. Limitations
6.7.4. Compatibility with guides

6.8. Rayplicker

6.8.1. Color Acquisition
6.8.2. Advantages
6.8.3. Compatibilities
6.8.4. Translucency

6.9. Materials

6.9.1. Zirconium
6.9.2. PMMA
6.9.3. Graphene
6.9.4. Zirconium plus ceramic

6.10. Connection with the Laboratory

6.10.1. Connection software
6.10.2. Use of digital models in the planning of dental work with the dental laboratory
6.10.3. Interpretation of reports and digital models received from the dental laboratory
6.10.4. Management of the differences between digital models and dental work fabricated in the dental laboratory

Module 7. Digital Flow and Guided Surgery. Planning & Software

7.1. Guided Surgery

7.1.1. Digital imaging technology and its use in guided surgery planning
7.1.2. Virtual planning of guided implants and their integration into clinical practice
7.1.3. Surgical splint design and its importance in guided surgery
7.1.4. Step-by-step guided surgery procedures and their clinical implementation

7.2. Guided Surgery Kit

7.2.1. Design and production of customized guided surgery kits for each case
7.2.2. Implementation of guided surgery kits in the digital workflow in the dental practice
7.2.3. Assessment of the accuracy of guided surgery kits in the planning and execution of guided surgery
7.2.4. Integration of guided surgery kits with guided surgery planning software and its impact on clinical efficiency

7.3. Nemoscan

7.3.1. File Import
7.3.2. Implant placement
7.3.3. Splint design
7.3.4. Stl Export

7.4. BSB

7.4.1. File Import
7.4.2. Implant placement
7.4.3. Splint design
7.4.4. Stl Export

7.5. BSP digital workflow

7.5.1. Design and production of occlusal splints using the BSP digital workflow
7.5.2. Assessment of the accuracy of occlusal splints produced with the BSP digital workflow
7.5.3. BSP digital workflow integration in the dental practice
7.5.4. Use of the BSP digital workflow in orthodontic treatment planning and delivery

7.6. Implant placement

7.6.1. Virtual planning of dental implant placement using 3D design software
7.6.2. Simulation of implant placement on 3D patient models
7.6.3. Use of surgical guides and guided surgery techniques in the placement of dental implants
7.6.4. Evaluation of the accuracy and effectiveness of implant placement with guided surgery

7.7. Design with BSB of tooth-supported splints

7.7.1. Functions and tools of BSB software in mucus-supported splints
7.7.2. Design of mucus-supported splints
7.7.3. Manufacture of mucus-supported splints
7.7.4. Fabrication of mucus-supported splints

7.8. Design of single implants with BSB

7.8.1. BSB software functions and tools for Unitary Implant
7.8.2. Unitary implant design
7.8.3. Unitary implant Fabrication
7.8.4. Unitary implant fitting and placement

7.9. Design of immediate implants with BSB

7.9.1. BSB software functions and tools for Immediate Implant
7.9.2. Immediate implant design
7.9.3. Immediate implant Fabrication
7.9.4. Immediate implant fitting and placement

7.10. Design with BSB of design of tooth-supported splints

7.10.1. BSB software functions and tools for surgical
7.10.2. Surgical splint design
7.10.3. Surgical splint Fabrication
7.10.4. Surgical splint fitting and placement

Module 8. Digital Flow. Endodontic and periodontal guides

8.1. Endodontic guides

8.1.1. Virtual planning of Endodontic guides placement using 3D design software
8.1.2. Assessment of the accuracy and effectiveness of digital flow for endodontic guide placement
8.1.3. Material selection and 3D printing techniques for the production of endodontic guides
8.1.4. Use of endodontic guides for root canal preparation

8.2. Import file in endodontic guides

8.2.1. 2D and 3D image file processing for virtual planning of endodontic guidewire placement
8.2.2. Assessment of the accuracy and effectiveness of digital flow for endodontic guide Education
8.2.3. Selection of 3D design software and file formats for import into endodontic guide planning
8.2.4. Customized design of endodontic guides using imported medical imaging files

8.3. Localization of the canal in endodontic guides

8.3.1. Digital image processing for virtual planning of root canal location in endodontic guidewires
8.3.2. Assessment of the accuracy and effectiveness of digital flow for endodontic guide Education
8.3.3. Selection of 3D design software and file formats for root canal location into endodontic guide planning
8.3.4. Customized design of endodontic guides using root canal location in planning

8.4. Fixing the endodontic guide ring

8.4.1. Assessment of different types of rings and their relationship to endodontic guidance accuracy
8.4.2. Material selection and 3D printing techniques for the production of endodontic guides
8.4.3. Assessment of the accuracy and effectiveness of digital flow for endodontic guide Education
8.4.4. Customized design of Endodontic guides Fixation using 3D design software

8.5. Dental anatomy and periapical structures in endodontic guides

8.5.1. Identification of key anatomical structures in the planning of endodontic guides
8.5.2. Anatomy of anterior and posterior teeth and its implications in endodontic guide planning
8.5.3. Considerations of and variations in the planning of endodontic guides
8.5.4. Dental anatomy in the planning of endodontic guides for complex treatments

8.6. Periodontal guides

8.6.1. Design and production of periodontal guides using digital planning software
8.6.2. Importing and recording CBCT image data for periodontal guide planning
8.6.3. Periodontal guide fixation techniques to ensure accuracy in surgery
8.6.4. Digital workflows for bone and soft-tissue graft placement in guided periodontal surgery

8.7. Import file in periodontal guides

8.7.1. Types of files used in the import of digital periodontal guides
8.7.2. Procedure for importing image files for the creation of digital periodontal guides
8.7.3. Technical considerations for file import in digital periodontal guide planning
8.7.4. Selection of suitable software for importing files into digital periodontal guides

8.8. Coronary lengthening guide design in periodontal guides

8.8.1. Definition and concept of coronary lengthening guide in dentistry
8.8.2. Indications and contraindications for the use of coronary lengthening guides in dentistry
8.8.3. Procedure for the digital design of coronary lengthening guidewires using specific software
8.8.4. Anatomical and esthetic considerations for the design of coronary lengthening guides in digital dentistry

8.9. stl export in periodontal guides

8.9.1. Dental anatomy and periodontal structures relevant to the design of periodontal and endodontic guides
8.9.2. Digital technologies used in the planning and design of endodontic and periodontal guides, such as computed tomography, magnetic resonance imaging and digital photography
8.9.3. Periodontal guide design
8.9.4. Endodontic guide design

8.10. Dental anatomy and periodontal structures

8.10.1. Virtual dental and periodontal anatomy
8.10.2. Design of customized periodontal guides
8.10.3. Evaluation of periodontal health using digital radiographs
8.10.4. Guided periodontal surgery techniques

Module 9. Digital Flow. Minimally invasive preparations, cam, laboratory and chairside systems

9.1. First fit veneer system

9.1.1. Record Keeping
9.1.2. Web Upload
9.1.3. Mockup
9.1.4. Milling sequence

9.2. Cementation in the clinic

9.2.1. Types of dental cements and their properties
9.2.2. Selection of the appropriate dental cement for each clinical case
9.2.3. Cementation protocol for veneers, crowns and bridges
9.2.4. Preparation of the tooth surface prior to cementation

9.3. Laboratory

9.3.1. Digital dental materials: types, properties and applications in Dentistry
9.3.2. Fabrication of ceramic veneers and crowns with CAD/CAM systems
9.3.3. Fabrication of fixed bridges using CAD/CAM systems
9.3.4. Fabrication of prosthesis using CAD/CAM systems

9.4. 3D Printing

9.4.1. Types of 3D printers used in digital dentistry
9.4.2. Design and 3D printing of studio and working models
9.4.3. 3D printing of surgical guides and surgical splints
9.4.4. 3D printing of surgical guides and surgical splints
9.4.5. 3D printing of Dental Prostheses

9.5. XY resolution and Z resolution

9.5.1. Selection and use of materials for digital dental restorations
9.5.2. Integration of digital dentistry in the clinic
9.5.3. XY resolution and Z resolution 3D printers
9.5.4. Virtual planning of dental restoration

9.6. Types of Resin

9.6.1. Resins for models
9.6.2. Sterilizable resins
9.6.3. Resins for temporary teeth
9.6.4. Resins for permanent teeth

9.7. Milling machines

9.7.1. Milling machines for direct restorations
9.7.2. Milling machines for Indirect restorations
9.7.3. Fissure sealers for fissure sealing and caries prevention
9.7.4. Orthodontic milling cutters

9.8. Sintering Furnaces

9.8.1. Sintering Furnaces and their role in the preparation of conservative dental crowns
9.8.2. Application of CAD/CAM technology for the preparation of minimally invasive preparations in digital dentistry
9.8.3. New techniques and digital technologies for minimally invasive preparation of dental inlays and onlays
9.8.4. Virtual tooth preparation software systems and their use in minimally invasive preparation planning

9.9. Model pro model manufacturing

9.9.1. Accurate model manufcaturing using intraoral scanning technology for minimally invasive preparations
9.9.2. Minimally invasive preparation planning using digital models and CAD/CAM technology
9.9.3. Manufacturing of models for the preparation of minimally invasive dental veneers
9.9.4. Digital Modes and their role in the preparation of conservative dental crowns

9.10. Dental printers vs. generic printers

9.10.1. Dental printers vs. generic printers
9.10.2. Comparison of the technical characteristics of dental and generic printers for the fabrication of dental restorations
9.10.3. Dental printers and their role in minimally invasive preparation of customized dentures
9.10.4. Generic printers and their adaptability to the fabrication of dental prostheses

Module 10. Virtual articulator and occlusion

10.1. Virtual articulator

10.1.1. Virtual articulator and its use in the planning of dental prostheses in digital dentistry
10.1.2. New techniques and digital technologies for the use of virtual articulators in digital dentistry
10.1.3. Occlusion in Digital Dentistry and its relation with the use of virtual articulator
10.1.4. Digital occlusion planning and the use of the virtual articulator in esthetic dentistry

10.2. TEKSCAN

10.2.1. File Import
10.2.2. Implant placement
10.2.3. Splint design
10.2.4. Stl Export

10.3. TEETHAN

10.3.1. File Import
10.3.2. Implant placement
10.3.3. Splint design
10.3.4. Stl Export

10.4. Different virtual articulators

10.4.1. The most important ones
10.4.2. Development and application of virtual articulator technologies in the evaluation and treatment of temporomandibular disorders (TMD)
10.4.3. Application of virtual articulator technologies in the planning of dental prostheses in digital dentistry
10.4.4. Use of virtual articulator technologies in the assessment and diagnosis of Personality Disorder of dental the occlusion in digital dentistry

10.5. Design of dental restorations and prostheses with virtual articulator

10.5.1. Use of virtual articulator in the design and fabrication of removable partial dentures in digital dentistry
10.5.2. Design of dental restorations with virtual articulator for patients with dental occlusion disorders in digital dentistry
10.5.3. Total denture design with virtual articulator in digital dentistry: planning, execution and follow-up
10.5.4. Use of virtual articulator in interdisciplinary orthodontic planning and design in digital dentistry

10.6. MODJAW

10.6.1. Use of MODJAW in orthodontic planning of treatments in digital dentistry
10.6.2. Application of MODJAW in the assessment and diagnosis of temporomandibular disorders (TMD) in digital dentistry
10.6.3. Use of MODJAW in the planning of dental prostheses in digital dentistry
10.6.4. MODJAW and its relationship to dental esthetics in digital dentistry

10.7. Positioning

10.7.1. Files
10.7.2. Tiara
10.7.3. Butterfly
10.7.4. Models

10.8. Transaction log

10.8.1. Protrusion
10.8.2. Opening
10.8.3. Lateralities
10.8.4. Chewing

10.9. Mandibular axis location

10.9.1. Centric Relation
10.9.2. Maximum opening without displacement
10.9.3. Click log
10.9.4. Bite restructuring

10.10. Export to design programs

10.10.1. Use of export to design programs in orthodontic treatment planning in digital dentistry
10.10.2. Application of export to design programs in the planning and design of dental prostheses in digital dentistry
10.10.3. Export to design programs and its relationship to dental esthetics in digital dentistry
10.10.4. Export to design programs in the assessment and diagnosis of dental occlusion disorders in Digital Dentistry

With this university proposal you will up-to-date your knowledge on the use of MODJAW in orthodontic treatment planning in Digital Dentistry”