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Machine learning unifies flexibility and efficiency of spinodal structure generation for stochastic biomaterial design

Zhuo Wang, Rana Dabaja, Lei Chen, Mihaela Banu

2023Scientific Reports25 citationsDOIOpen Access PDF

Abstract

Porous biomaterials design for bone repair is still largely limited to regular structures (e.g. rod-based lattices), due to their easy parameterization and high controllability. The capability of designing stochastic structure can redefine the boundary of our explorable structure-property space for synthesizing next-generation biomaterials. We hereby propose a convolutional neural network (CNN) approach for efficient generation and design of spinodal structure-an intriguing structure with stochastic yet interconnected, smooth, and constant pore channel conducive to bio-transport. Our CNN-based approach simultaneously possesses the tremendous flexibility of physics-based model in generating various spinodal structures (e.g. periodic, anisotropic, gradient, and arbitrarily large ones) and comparable computational efficiency to mathematical approximation model. We thus successfully design spinodal bone structures with target anisotropic elasticity via high-throughput screening, and directly generate large spinodal orthopedic implants with desired gradient porosity. This work significantly advances stochastic biomaterials development by offering an optimal solution to spinodal structure generation and design.

Topics & Concepts

Flexibility (engineering)SpinodalBiomaterialComputer scienceSpinodal decompositionArtificial intelligenceMaterials scienceMathematicsChemistryNanotechnologyStatisticsPhase (matter)Organic chemistryMachine Learning in Materials ScienceAdditive Manufacturing and 3D Printing TechnologiesCellular and Composite Structures
Machine learning unifies flexibility and efficiency of spinodal structure generation for stochastic biomaterial design | Litcius