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Data-Driven Design and Additive Manufacturing of Patient-Specific Lattice Titanium Scaffolds for Mandibular Bone Reconstruction

Nail Beisekenov, Bagdat Azamatov, Marzhan Anuarbekovna Sadenova, Dmitriy Dogadkin, Daniyar Kaliyev, Sergey Rudenko, B. V. Syrnev

2025Journal of Functional Biomaterials8 citationsDOIOpen Access PDF

Abstract

The reconstruction of segmental bone defects requires patient-specific scaffolds that combine mechanical safety, biological functionality, and rapid manufacturing. We converted CT-derived mandibular geometry into a functionally graded Ti-6Al-4V lattice and optimised porosity, screw layout, and strut thickness through a cyber-physical loop that joins high-fidelity FEM, millisecond ANN, and a BN for uncertainty quantification. Fifteen candidate scaffolds were fabricated by direct metal laser sintering and hot isostatic pressing and were mechanically tested. FEM predicted stress and stiffness with 98% accuracy; the ANN reproduced these outputs with 94% fidelity while evaluating 10,000 designs in real time, and the BN limited failure probability to <3% under worst-case loads. The selected 55-65% porosity design reduced titanium use by 15%, shortened development time by 25% and raised multi-objective optimisation efficiency by 20% relative to a solid-plate baseline, while resisting a 600 N bite with a peak von Mises stress of 225 MPa and micromotion < 150 µm. Integrating physics-based simulation, AI speed, and probabilistic rigour yields a validated, additively manufactured scaffold that meets surgical timelines and biomechanical requirements, offering a transferable blueprint for functional scaffolds in bone and joint surgery.

Topics & Concepts

Materials sciencevon Mises yield criterionScaffoldComposite materialFinite element methodStiffnessTitaniumPorosityTitanium alloy3D printingStereolithographyStress (linguistics)Selective laser sinteringHot isostatic pressingBiomechanicsBiomedical engineeringCompressive strengthStress shieldingLattice (music)MagnetJoint (building)FrettingVoxelClampingElasticity (physics)PressingDirect metal laser sinteringSinteringMaterial propertiesContact mechanicsAdditive Manufacturing and 3D Printing TechnologiesAdditive Manufacturing Materials and ProcessesBone Tissue Engineering Materials
Data-Driven Design and Additive Manufacturing of Patient-Specific Lattice Titanium Scaffolds for Mandibular Bone Reconstruction | Litcius