Archive/Comparative Hydrodynamic Analysis and Optimization of Gyroid and Diamond Scaffolds with Functionally Graded Porosity
Comparative Hydrodynamic Analysis and Optimization of Gyroid and Diamond Scaffolds with Functionally Graded Porosity
Boming Gong, Jia’ao Zhu, Yun Guo et al.
3 juillet 2026
en

Abstract

This study presents a numerical investigation into the hydrodynamic and biomechanical performance of bone-repair scaffolds based on Triply Periodic Minimal Surfaces (TPMSs). Focusing on Gyroid and Diamond architectures, scaffolds with uniform (40–70%) and functionally graded porosities were developed. Computational Fluid Dynamics (CFD) simulations were employed to evaluate permeability, pressure drop, and Wall Shear Stress (WSS) distributions. Results indicate distinct topological advantages: the Gyroid structure demonstrates superior permeability and uniform WSS distribution due to its isotropic fluid channels, whereas the Diamond structure maintains better flow velocity stability. Crucially, the introduction of a porosity gradient (40–60%) successfully mitigates localized pressure surges and optimizes the bioactive WSS window for cell differentiation. Notably, increasing porosity to 70% in Gyroid scaffolds yielded a 277% enhancement in permeability. These findings establish a theoretical basis for designing functionally graded TPMS scaffolds that balance fluid transport efficiency with a favorable cellular microenvironment.

IPC Classification

C07B60

Keywords

comparativehydrodynamicanalysisoptimizationgyroiddiamondscaffoldsfunctionallygradedporosityjournalfunctionalbiomaterialspresentsnumericalinvestigationbiomechanicalperformancebone-repairbasedtriplyperiodicminimalsurfaces
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