Matricúlate ahora en una oportunidad académica que te convertirá en el odontólogo que domine los procedimientos clínicos más innovadores” 

Crear restauraciones dentales personalizadas que se ajustan a la sonrisa y la estética facial del paciente es algo cada vez menos laborioso gracias a la Digitalización de los procedimientos clínicos. A través del Flujo Digital en la Planificación Estética, hoy los odontólogos pueden capturar útiles imágenes digitales de la boca y la cara del paciente, crear modelos 3D a partir de ellas y planificar un tratamiento estético utilizando el Software DSD. Se trata de solo un ejemplo de todas las posibilidades que ofrecen en la actualidad los flujos digitales, así que es imperativo que este profesional sanitario se actualice en estas técnicas innovadoras. 

De hecho, es algo que podrá hacer con las mayores garantías gracias a TECH, pues esta Postgraduate diploma sumergirá al odontólogo en la práctica odontológica más vanguardista y eficiente. Con tal fin, se hará especial énfasis en la Cirugía Guiada y sus kits, el flujo de trabajo digital BSP, la colocación de implantes o el diseño de férulas mucosoportadas y de implantes unitarios, entre otros puntos clave. Del mismo modo, perfeccionará su práctica clínica en la planificación virtual de la colocación de guías endodónticas utilizando Software de diseño 3D e identificará la anatomía dental y estructuras periapicales en estas guías. 

Todo esto y más en un recorrido académico condensado en 600 horas. Asimismo, la Postgraduate diploma es 100% online, lo que permite a los estudiantes acceder a los contenidos en cualquier momento y lugar. Dispondrán, además, de un gran equipo docente compuesto por profesionales con amplia experiencia en la práctica clínica y en la preparación de alto nivel de alumnos de Odontología.  

Fortalece tus destrezas desde casa o cualquier lugar en la planificación virtual de guías endodónticas a través de Software especializado”

Esta Postgraduate diploma en Clinical Procedures in Digital Dentistry contiene el programa científico más completo y actualizado del mercado. Sus características más destacadas son:

• El desarrollo de casos prácticos presentados por expertos en Clinical Procedures in Digital Dentistry
• Los contenidos gráficos, esquemáticos y eminentemente prácticos con los que está concebido recogen una información científica y práctica sobre aquellas disciplinas indispensables para el ejercicio profesional 
• Los ejercicios prácticos donde realizar el proceso de autoevaluación para mejorar el aprendizaje 
• Su especial hincapié en metodologías innovadoras  
• Las lecciones teóricas, preguntas al experto, foros de discusión de temas controvertidos y trabajos de reflexión individual 
• La disponibilidad de acceso a los contenidos desde cualquier dispositivo fijo o portátil con conexión a internet 

Serás una referencia a la hora de fabricar férulas mucosoportadas gracias a los ejercicios autoevaluativos y casos prácticos que realizarás”   

El programa incluye en su cuadro docente a profesionales del sector que vierten en esta capacitación la experiencia de su trabajo, además de reconocidos especialistas de sociedades de referencia y universidades de prestigio.  

Su contenido multimedia, elaborado con la última tecnología educativa, permitirá al profesional un aprendizaje situado y contextual, es decir, un entorno simulado que proporcionará una capacitación inmersiva programada para entrenarse ante situaciones reales.  

El diseño de este programa se centra en el Aprendizaje Basado en Problemas, mediante el cual el profesional deberá tratar de resolver las distintas situaciones de práctica profesional que se le planteen a lo largo del curso académico. Para ello, contará con la ayuda de un novedoso sistema de vídeo interactivo realizado por reconocidos expertos.   

Determina como un experto el ajuste y colocación del implante inmediato con el extenso abanico de recursos alojados en el Campus Virtual. 

No dejes pasar la oportunidad de integrar el Flujo Digital en la fabricación de Mockups gracias a TECH. 

This program has been designed in collaboration with the teacher's team, offering a highly flexible structure and content that adapts to the needs and availability of the students. With a practical and applied approach, the program is divided into four modules that comprehensively cover the latest Clinical Procedures in Digital Dentistry. In addition, Relearning is used as a methodological substrate, based on the directed reiteration of the concepts of the syllabus through dynamic educational resources. Some of them are self-awareness exercises, master classes or interactive summaries.

Test everything you have studied in the Postgraduate diploma by doing useful self-knowledge exercises"

Module 1. Digital Flow and Invisible Orthodontics Planning and software

1.1. Different Software Available to Create

1.1.1. Open Source
1.1.2. BSB
1.1.3. Code Closed
1.1.4. Teacher

1.2. Nemocast

1.2.1. Import, Orientation
1.2.2. Top and Bottom Model Segmentation
1.2.3. Setup and Placement of Cofferdams
1.2.4. Stl Export

1.3. Blue Sky Bio

1.3.1. Import, Orientation
1.3.2. Top and Bottom Model Segmentation
1.3.3. Setup and Placement of Cofferdams
1.3.4. Stl Export

1.4. Teacher

1.4.1. Import, Orientation
1.4.2. Top and Bottom Model Segmentation
1.4.3. Setup and Placement of Cofferdams
1.4.4. Stl Export

1.5. Study Models

1.5.1. Studies Models Types
1.5.2. Advantages and Disadvantages of Digital Studio Models
1.5.3. Scanning Process of Physical Study Models
1.5.4. Digital Study Model Creation Process

1.6. Template Placement for Brackets

1.6.1. What Is a Bracket Template?
1.6.2. Design
1.6.3. Materials Used
1.6.4. Adjustments

1.7. Masks and Positioning Guides for Cofferdams

1.7.1. What Are Attachments in Invisible Orthodontics?
1.7.2. What Are Masks and Positioning Guides for Attachments?
1.7.3. Design and Manufacturing Process for Masks and Positioning Guides for Cofferdam Attachments
1.7.4. Materials Used in the Manufacture of Masks and Positioning Guides for Attachments

1.8. Different Brands of Invisible Aligners

1.8.1. Invisaline
1.8.2. Spark
1.8.3. Smilers
1.8.4. Clear Correct

1.9. Digital Mockup

1.9.1. Concept and Application of Digital Mockup in Invisible Orthodontics
1.9.2. Workflow for the Creation of a Digital Mockup
1.9.3. Use of Digital Tools for Case Planning in Invisible Orthodontics
1.9.4. Clinical Case Analysis and Examples of Digital Mockup Application

1.10. Mouth Scanning

1.10.1. 3D Upper Jaw
1.10.2. Lower Jaw
1.10.3. Bites
1.10.4. Revision of the Model

Module 2. Digital Flow and Aesthetic Planning DSD

2.1. DSD

2.1.1. 2D Proportions
2.1.2. 3D Proportions
2.1.3. Aesthetic Planning
2.1.4. File Export

2.2. Software

2.2.1. DSD1
2.2.2. Export Design
2.2.3. Aesthetic Planning
2.2.4. File Export

2.3. Design

2.3.1. Virtual Simulation of Treatments and Its Importance in Aesthetic Planning
2.3.2. Designing Aesthetic Dental Restorations Using Digital Design
2.3.3. Tooth Preparation Techniques for the Design of Aesthetic Dental Restorations
2.3.4. Cementing and Bonding Techniques for Aesthetic Dental Restorations

2.4. Proportions

2.4.1. Dental and Facial Anatomy Applied to the Analysis of Proportions
2.4.2. Ideal Dental and Facial Proportions in the Smile and Their Relationship to Facial Aesthetics
2.4.3. Importance of Ratio Analysis in Implant Dentistry Treatment Planning
2.4.4. Integration of Proportion Analysis into the Patient's Overall Aesthetic Planning

2.5. Mockup Manufacturing

2.5.1. Use of Mockup in Aesthetic Treatment Planning
2.5.2. Use of Mockup in Implant Dentistry Treatment Planning
2.5.3. Use of Mockup for Smile Design Presentation to the Patient and Interdisciplinary Communication
2.5.4. Integration of the Digital Flow in the Manufacture of Mockups

2.6. Digital Color Acquisition

2.6.1. Data Science
2.6.2. Color Map
2.6.3. Laboratory Communication
2.6.4. Communication with Patient

2.7. Vita

2.7. 1 Equipment
2.7.2. Color Pick-Up Zones
2.7.3. Limitations
2.7.4. Compatibility with Guides

2.8. Rayplicker

2.8.1. Color Acquisition
2.8.2. Advantages
2.8.3. Compatibility
2.8.4. Translucency

2.9. Materials

2.9.1. Zirconium
2.9.2. PMMA
2.9.3. Graphene
2.9.4. Zirconium Plus Ceramic

2.10. Connection with the Laboratory

2.10.1. Connection Software
2.10.2. Use of Digital Models in the Planning of Dental Work with the Dental Laboratory
2.10.3. Interpretation of Reports and Digital Models Received from the Dental Laboratory
2.10.4. Management of the Differences Between Digital Models and Dental Work Fabricated in the Dental Laboratory

Module 3. Digital Flow and Guided Surgery Planning and software

3.1. Guided Surgery

3.1.1. Digital Imaging Technology and Its Use in Guided Surgery Planning
3.1.2. Virtual Planning of Guided Implants and Their Integration into Clinical Practice
3.1.3. Surgical Splint Design and Its Importance in Guided Surgery
3.1.4. Step-by-Step Guided Surgery Procedures and Their Clinical Implementation

3.2. Guided Surgery Kits

3.2.1. Design and Production of Customized Guided Surgery Kits for Each Case
3.2.2. Implementation of Guided Surgery Kits in the Digital Work Flow in the Dental Practice
3.2.3. Assessment of the Accuracy of Guided Surgery Kits in the Planning and Execution of Guided Surgery
3.2.4. Integration of Guided Surgery Kits with Guided Surgery Planning Software and Its Impact on Clinical Efficiency

3.3. Nemoscan

3.3.1. File Import
3.3.2. Implant Placement
3.3.3. Splint Design
3.3.4. Stl Export

3.4. BSB

3.4.1. File Import
3.4.2. Implant Placement
3.4.3. Splint Design
3.4.4. Stl Export

3.5. BSP Digital Work Flow

3.5.1. Design and Production of Occlusal Splints Using the BSP Digital Work Flow
3.5.2. Assessment of the Accuracy of Occlusal Splints Produced with the BSP Digital Work Flow
3.5.3. BSP Digital Work Flow Integration in the Dental Practice
3.5.4. Use of the BSP Digital Work Flow in Orthodontic Treatment Planning and Delivery

3.6. Implant Placement

3.6.1. Virtual Planning of Dental Implant Placement Using 3D Design Software
3.6.2. Simulation of Implant Placement on 3D Patient Models
3.6.3. Use of Surgical Guides and Guided Surgery Techniques in the Placement of Dental Implants
3.6.4. Assessment of the Accuracy and Effectiveness of Implant Placement with Guided Surgery

3.7. Design with BSB of Mucosa-Supported Splints

3.7.1. Functions and Tools of BSB Software in Mucosa-Supported Splints
3.7.2. Design of Mucosa-Supported Splints
3.7.3. Fabrication of Mucosa-Supported Splints
3.7.4. Fitting and Placement of Mucosa-Supported Splints

3.8. Design of Single Implants with BSB

3.8.1. Functions and Tools of the BSB Software in Single Implant
3.8.2. Design of Single Implants
3.8.3. Fabrication of Single Implants
3.8.4. Adjustment and Placement of Single Implants

3.9. Immediate Implant BSB Design

3.9.1. Functions and Tools of the BSB Software in Immediate Implant
3.9.2. Immediate Implant Design
3.9.3. Immediate Implant Fabrication
3.9.4. Immediate Implant Fitting and Placement

3.10. Design with BSB of Surgical Splint Design

3.10.1. Functions and Tools of BSB Software in Surgical Splinting
3.10.2. Surgical Splint Design
3.10.3. Fabrication of Surgical Splint
3.10.4. Adjustment and Placement of Surgical Splint

Module 4. Digital Flow Endodontic and periodontal guides

4.1. Endodontic Guides

4.1.1. Virtual Planning of Endodontic Guidewire Placement Using 3D Design Software
4.1.2. Assessment of the Accuracy and Effectiveness of Digital Flow for Endodontic Guidewire Placement
4.1.3. Material Selection and 3D Printing Techniques for the Production of Endodontic Guides
4.1.4. Use of Endodontic Guides for Root Canal Preparation

4.2. Import File in Endodontic Guides

4.2.1. 2D and 3D Image File Processing for Virtual Planning of Endodontic Guidewire Placement
4.2.2. Assessment of the Accuracy and Effectiveness of File Import in Endodontic Guide Planning
4.2.3. Selection of 3D Design Software and File Formats for Import into Endodontic Guide Planning
4.2.4. Customized Design of Endodontic Guides Using Imported Medical Image Files

4.3. Localization of the Canal in Endodontic Guides

4.3.1. Digital Image Processing for Virtual Planning of Root Canal Location in Endodontic Guidewires
4.3.2. Assessment of the Accuracy and Effectiveness of Root Canal Location in Endodontic Guide Planning
4.3.3. Selection of 3D Design Software and File Formats for Root Canal Location in Endodontic Guide Planning
4.3.4. Customized Design of Endodontic Guides Using Root Canal Location in Planning

4.4. Fixing the Endodontic Guide Ring

4.4.1. Assessment of Different Types of Rings and Their Relationship to Endodontic Guidance Accuracy
4.4.2. Selection of Materials and Techniques for the Fixation of the Ring in the Endodontic Guide
4.4.3. Assessment of the Accuracy and Effectiveness of Ring Fixation in Endodontic Guidance
4.4.4. Custom Design of the Ring Fixation on the Endodontic Guide Using 3D Design Software

4.5. Dental Anatomy and Periapical Structures in Endodontic Guides

4.5.1. Identification of Key Anatomical Structures in the Planning of Endodontic Guides
4.5.2. Anatomy of Anterior and Posterior Teeth and Its Implications in Endodontic Guide Planning
4.5.3. Anatomy Considerations and Variations in Endodontic Guide Planning
4.5.4. Dental Anatomy in the Planning of Endodontic Guides for Complex Treatments

4.6. Periodontal Guides

4.6.1. Design and Production of Periodontal Guides Using Digital Planning Software
4.6.2. Importing and Recording CBCT Image Data for Periodontal Guide Planning
4.6.3. Periodontal Guide Fixation Techniques to Ensure Precision in Surgery
4.6.4. Digital Work Flows for Bone and Soft-Tissue Graft Placement in Guided Periodontal Surgery

4.7. Import File in Periodontal Guides

4.7.1. Types of Files Used in the Import of Digital Periodontal Guides
4.7.2. Procedure for Importing Image Files for the Creation of Digital Periodontal Guides
4.7.3. Technical Considerations for File Import in Digital Periodontal Guide Planning
4.7.4. Selection of Suitable Software for Importing Files into Digital Periodontal Guides

4.8. Coronary Lengthening Guide Design in Periodontal Guides

4.8.1. Definition and Concept of Coronary Lengthening Guide in Dentistry
4.8.2. Indications and Contraindications for the Use of Coronary Lengthening Guides in Dentistry
4.8.3. Procedure for the Digital Design of Coronary Lengthening Guidewires Using Specific Software
4.8.4. Anatomical and Aesthetic Considerations for the Design of Coronary Lengthening Guides in Digital Dentistry

4.9. Stl Export in Periodontal Guides

4.9.1. Dental Anatomy and Periodontal Structures Relevant to the Design of Periodontal and Endodontic Guides
4.9.2. Digital Technologies Used in the Planning and Design of Endodontic and Periodontal Guides, such as Computed Tomography, Magnetic Resonance Imaging and Digital Photography
4.9.3. Periodontal Guide Design
4.9.4. Endodontic Guide Design

4.10. Dental Anatomy and Periodontal Structures

4.10.1. Virtual Dental and Periodontal Anatomy
4.10.2. Design of Customized Periodontal Guides
4.10.3. Assessment of Periodontal Health Using Digital Radiographs
4.10.4. Guided Periodontal Surgery Techniques

You will only need a device with an Internet connection to launch your professional career based on the latest technological advances in Digital Dentistry"