The All-In-One® Workflow: Extract - Implant - Restore All in One Session

– Biological, biomechanical, and technical risk factors determining success and failure in immediate full-arch rehabilitation
– The complete All-In-One® workflow: step-by-step decision algorithm from the first patient appointment through extraction, implant placement, and provisional delivery
– Indications for 4 vs. 6 implants: bone quality and quantity, arch configuration, occlusal load distribution, and prosthetic design criteria
– Anaesthesia and sedation protocols: local anaesthesia, intravenous sedation, and general anaesthesia indications
– Bone reduction planning based on bone resorption levels and gingival display during full smile
– Transition line design principles: planning, common mistakes, and correction of compromised transition lines
– Guided full-arch surgery: indications, contraindications, workflow, precision limitations, and integration with the All-In-One® concept
– Bicortical implant placement in the maxilla: three-dimensional positioning for reliable immediate-loading primary stability
– Avoidance of inadequate stability and excessive torque during maxillary implant placement
– Mandibular implant positioning: nerve localisation, safe proximity placement, tilted vs. axial implant selection, guided vs. freehand execution, and anterior mandibular anatomical landmarks.

– Epidemiological context of peri-implantitis and implant failure in severely resorbed edentulous maxillae
– General principles of graftless atrophic maxilla rehabilitation: patient selection, risk stratification, and prosthetic planning prior to surgical sequencing
– The PATZI protocol: systematic decision-making matrix based on residual bone anatomy
– Anterior nasal implants: nasal vomer anchorage, nasal spine, nasal floor engagement, and the trans-nasal approach
– Anatomy, technique, indications, and complications of trans-nasal implant approaches
– Pterygoid implants: three-dimensional angulation for cortical engagement of the pterygoid process
– Prosthetic implications and comparison of pterygoid implants with alternative posterior anchorage solutions
– Tilted implant strategies in intermediate resorption cases: M-technique and V-technique
– Long implants and palatal approach implants in graftless rehabilitation
– Trans-sinus implants: Bedrossian Zones I–IV and the ZAGA concept
– -Tilting strategies and the contributions of Maló, Aparicio, Bedrossian, and Davó
– Zygomatic implants: neck positioning in anterior, premolar, and molar zones
– Single vs. quad-zygoma configurations and indications for each strategy
– Integration of zygomatic implants into prosthetic design
– Combining remote anchorage techniques in hybrid full-arch configurations
– Load distribution principles and sequencing during the same surgical session.

– Evidence base of guided implant surgery: accuracy, complications, and failure risk compared with freehand and navigator-assisted placement
– Critical analysis of current literature on guided implantology
– Guided vs. flapless surgery: clarifying the distinction between concepts
– Static guided surgery for single units and short spans
– Drilling protocols, sleeve-to-implant accuracy, guided key vs. full-guided protocols, and offset mechanics
– Common errors in single-unit guided implant placement
– Full-arch guided surgery protocols within the All-In-One® concept
– CBCT acquisition standards, diagnostic wax-up, and virtual planning workflows
– Guide design for immediate-loading cases and integration with prosthetic conversion
– Impact of bone reduction and flap elevation on guide fit and surgical accuracy
– Static guided surgery for severely resorbed maxillae
– Guided zygomatic and pterygoid implant placement: anatomical planning and safe angulation design
– Guide design considerations for extraoral implant trajectories
– Clinical evidence comparing guided and freehand zygomatic surgery
– Dynamic navigation in implantology: principles, indications, and limitations
– Differences between real-time navigation and static guidance systems
– Stackable guides and immediate temporaries in full-arch rehabilitation
– Simultaneous fabrication of surgical guides and immediate provisional restorations
– Workflow integration, material selection, and conversion protocols for stackable systems
– Guided surgery in totally edentulous patients
– Fixation pin requirements and management of guide-to-bone gaps in severe alveolar resorption cases.

– Defining trans-sinus implants: length, angulation, crestal engagement, and sinus cavity trajectory
– Bedrossian Zones and their practical implications for trans-sinus case selection
– Historical development and contributions to the trans-sinus concept
– Residual crestal bone height requirements for safe trans-sinus placement
– Favourable vs. unfavourable sinus anatomy and sinus floor topography
– Membrane integrity assessment on CBCT and cone beam pre-surgical planning
– Patient-level risk factors: sinusitis history, anatomical variants, systemic conditions, and antibiotic prophylaxis
– Comparative analysis of trans-sinus and zygomatic implants
– Decision criteria for trans-sinus, zygomatic, and combined implant approaches
– Trans-sinus implants with or without membrane elevation and bone grafting
– Standard trans-sinus technique: pre-surgical CBCT analysis and virtual implant planning
– Flap design, crestal access, and osteotomy preparation through the sinus floor
– Controlled membrane management and implant trajectory control
– Implant selection, primary stability assessment, and immediate loading criteria
– Modified “Wand” technique for buccal bone anchoring
– Buccal cortical plate engagement as an additional anchorage point
– Modified osteotomy trajectory and implant angulation planning
– Stabilisation mechanics and biomechanical rationale of the “Wand” technique
– Enhanced primary stability in low-density posterior maxillary bone
– Improved biomechanical load distribution with shorter implants
– Direct visualization of apical implant engagement
– Comparison of trans-sinus implants with sinus lifting procedures.