Rehabilitation of severely atrophic edentulous maxillae with dental implants pose a significant clinical challenge. Immediate loading in grafted bone is often debated due to concerns about stress distribution and osseointegration. This study aimed to compare stress distribution in the maxilla using three full-arch implant configurations-all-on-four, all-on-six, and quad-zygomatic implants-in a single patient, to determine the safest and most favorable approach for immediate loading in grafted bone. Two CBCT scans from a 64-year-old female patient, before and after bone grafting (allograft with onlay grafting and sinus augmentation), were used to generate three patient-specific finite element models. Each model included the maxilla, implants in the respective configuration, abutments, and a full-arch prosthesis. Von Mises stresses in cortical and cancellous bone, implants, abutments, and prosthesis, as well as maximum bone displacement, were analyzed. Our results demonstrated that the all-on-six configuration provided the most favorable biomechanical outcome, with homogeneous cortical stress distribution, reduced stress in implants and prosthesis, and bone displacement fully compatible with immediate loading in grafted bone. The all-on-four model showed stress peaks at tilted abutments and cantilevers, whereas the quad-zygomatic model distributed implant and abutment stresses efficiently but induced higher cortical bone stresses, still within physiological limits.This patient-specific digital twin study demonstrates that immediate loading in full-arch grafted bone is biomechanically safe and optimal, with the all-on-six configuration providing superior stress distribution. These findings support clinical decision-making for immediate loading protocols and highlight the value of patient-specific FEA in planning complex maxillary rehabilitations.
Study Type
OBSERVATIONAL
Enrollment
1
CBTS Scans (Cone Beam Computed Tomography) perform as part of routine care
CHU de Nice
Nice, Alpes Maritimes, France
Stress distribution in the Maxillary Bone
Finite element analysis (FEA) a numerical simulation method that models how mechanical forces affect anatomical structures. This technique visualizes stress, tension, compression and displacement zones in the maxillary bone. Stress values are expressed in megapascals (MPa) and displacements in microns (μm).
Time frame: At inclusion
Stress distribution in the Implants
Finite element analysis (FEA). This technique visualizes stress, tension, compression and displacement zones in the implant. Stress values are expressed in megapascals (MPa) and displacements in microns (μm).
Time frame: At inclusion
Stress distribution in the Prosthesis
Finite element analysis (FEA). This technique visualizes stress, tension, compression and displacement zones in the prosthesis. Stress values are expressed in megapascals (MPa) and displacements in microns (μm).
Time frame: At inclusion
Accuracy of the digital model digital twin of real patient
Scan of his edentulous maxilla
Time frame: At inclusion
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