Formation

Summary: An in-depth course on the physical and biological principles of controlled tooth movement. It covers anchorage, force systems, moments, and torque control using fixed appliances within the Orthoprogressive framework.

Objectives:

• Understand biomechanical principles of tooth and tissue movement.
• Design efficient force systems for various malocclusions.
• Integrate biomechanics into Orthoprogressive treatment protocols.
• Apply diagnostic criteria for orthodontic and surgical cases.
• Select appropriate appliances based on clinical conditions.

Summary:An interdisciplinary course exploring the anatomy and physiology of the nervous system as applied to orofacial motor and sensory control. Designed for dentists, orthodontists, speech therapists, and physiotherapists within the Orthoprogressive functional approach.

Objectives:

• Analyze the relationship between the nervous system and orofacial function.
• Identify neuromotor pathways involved in mastication, swallowing, and phonation.
• Relate neuromuscular dysfunctions to orthodontic and orthopedic alterations.
• Integrate speech therapy and orthodontics within Orthoprogressive protocols.
• Apply strategies for functional assessment and rehabilitation.

Summary:  An integrative approach that emphasizes cooperation among orthodontics, speech therapy, and related fields. The course enhances interdisciplinary communication and the functional management of Orthoprogressive patients.
Objectives:

• Analyze the relationship between orofacial function and dentomaxillary development.

• Coordinate treatments among orthodontists, speech therapists, and physiotherapists.

• Design shared clinical protocols for functional stability.

• Apply Orthoprogressive diagnostic and complementary appliance systems according to patient needs.

• Promote a comprehensive vision of interdisciplinary orthodontic treatment.

Summary: A detailed study of the biological and morphogenetic foundations of facial growth, integrated into Orthoprogressive diagnostic and therapeutic planning.
Objectives:

• Understand the biology of facial and skeletal growth.
• Evaluate genetic, functional, and environmental factors.
• Relate developmental stages to progressive therapeutic strategies.
• Select interceptive appliances appropriate for each stage.
• Integrate orthodontic and surgical diagnosis within the Orthoprogressive framework.

Summary: An advanced review of Ricketts’ philosophy and its evolution toward the Orthoprogressive concept. Covers clinical stages, anchorage sequencing, force systems, and the customized design of appliances.
Objectives:

• Understand the bioprogressive philosophy and its adaptation to Orthoprogressive.
• Apply comprehensive diagnostic criteria for complex and surgical treatments.
• Plan the clinical sequence from diagnosis to retention.
• Incorporate Orthoprogressive prefabricated appliances as tools for force control.
• Solve clinical compromises through progressive and controlled approaches.

Summary: An advanced course focused on the study, planning, and clinical implementation of Temporary Anchorage Devices (TADs) and microscrew as tools for absolute anchorage in orthodontics. It covers biomechanical principles, selection criteria, surgical protocols, and clinical applications within the Orthoprogressive planing. Includes a comparative analysis of conventional versus absolute anchorage and integration with Orthoprogressive prefabricated appliances.

Objectives:

• Understand the biomechanical and biological foundations of TADs and microimplants.
• Determine indications, safe zones, and insertion techniques for different clinical scenarios.
• Integrate TADs into the design of controlled and predictable force systems.
• Apply diagnostic criteria for orthodontic, surgical, and compromise patients.
• Select the appropriate Orthoprogressive complementary appliances according to the anchorage type.
• Develop skills for interdisciplinary planning with surgery and periodontics.
• Evaluate long-term stability and management of clinical complications.

Summary: An advanced comparative course analyzing major orthodontic systems and clinical philosophies, advantages and disadvantages, focused on scientific, biomechanical, and therapeutic criteria. Within the Orthoprogressive framework, systems such as lingual , ceramics and  self-ligating brackets, aligners, low-friction mechanics, MBT, and Roth are contrasted, emphasizing evidence-based advantages, limitations, and outcomes. The course encourages critical thinking and rational appliance selection based on patient type and treatment goals.

Objectives:

• Analyze biomechanical, clinical, and philosophical differences among major orthodontic systems.
• Review current scientific evidence regarding efficiency, movement control, and long-term stability.
• Understand the integration of each system within the Orthoprogressive philosophy.
• Apply diagnostic and appliance selection criteria according to malocclusion, biotype, and esthetic goals.
• Develop critical ability to combine elements from multiple systems (clinical hybrids) for personalized treatments.
• Assess functional and biological impacts in treatments using brackets and aligners.
• Analyze real clinical cases through comparative  approaches.

Summary: A theoretical–practical course focused on the design, fabrication, and optimization of orthodontic appliances . Includes hands-on training in EPR expanders, anchorage devices, retainers, acrylic appliances, and Orthoprogressive hybrid systems, as well as techniques in welding, polishing, and digital modeling. Also covers 3D printing and digital workflow in modern orthodontics.

Objectives:

• Understand the biomechanical and structural principles in orthodontic appliance design.
• Develop practical skills for fabricating expanders, retainers, and functional appliances.
• Apply welding, wire bending, and acrylic processing techniques according to Orthoprogressive protocols.
• Integrate digital impression and CAD/CAM design tools into orthodontic laboratory procedures.
• Establish appliance selection criteria based on clinical diagnosis.
• Implement quality control  in appliance fabrication.
• Evaluate the advantages of fabricating your own orthodontic appliances, optimizing clinical customization and treatment control.