Archive/Copper-Doped Silicate Porous Architectures for Hard Tissue Engineering
Copper-Doped Silicate Porous Architectures for Hard Tissue Engineering
Cristina Cristea, Maria-Eliza Puscasu, Gabriela-Olimpia Isopencu et al.
July 9, 2026
en

Abstract

Porous silicate scaffolds represent a promising class of grafting materials for hard tissue engineering due to their superior bioactivity, adjustable degradation rates, and ability to stimulate both osteogenesis and angiogenesis. In this work, scaffolds based on an akermanite-targeted (Ca2MgSi2O7) starting composition, including copper-doped variants, were synthesized using sol–gel and combustion routes, followed by 3D printing to achieve porous architectures with controlled pore size and interconnectivity. The powders were characterized by scanning electron microscopy, energy-dispersive X-ray spectroscopy, Fourier transform infrared spectroscopy, X-ray diffraction, and thermal analysis to evaluate their morphology, composition, and crystalline phases. The scaffolds were further assessed in terms of bioactivity by immersion in simulated body fluid (SBF), antibacterial activity, and in vitro cellular response. The results confirmed that copper doping enhanced antibacterial properties, while maintaining favorable biological behavior. Comparative analysis revealed differences between the two synthesis methods, with sol–gel providing more homogeneous structures and combustion leading to highly porous morphologies. These findings highlight copper-doped silicate scaffolds as promising candidates for bone tissue regeneration, combining architectural integrity with biological functionality.

IPC Classification

C07A01B60H01

Keywords

copper-dopedsilicateporousarchitectureshardtissueengineeringjournalfunctionalbiomaterialsscaffoldsrepresentpromisingclassgraftingmaterialssuperiorbioactivityadjustabledegradationratesabilitystimulateboth
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