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Controlling the microstructure of lyophilized porous biocomposites by the addition of ZnO‐doped bioglass
Author(s) -
Ciołek Lidia,
Biernat Monika,
Jaegermann Zbigniew,
TymowiczGrzyb Paulina,
Taźbierski Piotr,
Jastrzębska Agnieszka,
Olszyna Andrzej
Publication year - 2017
Publication title -
international journal of applied ceramic technology
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.4
H-Index - 57
eISSN - 1744-7402
pISSN - 1546-542X
DOI - 10.1111/ijac.12739
Subject(s) - microstructure , materials science , composite number , simulated body fluid , porosity , polymer , chemical engineering , apatite , composite material , solvent , layer (electronics) , scanning electron microscope , chemistry , organic chemistry , engineering
Abstract The study presents the results of the study on porous composite biomaterials obtained using lyophilization method based on polymer solutions: chitosan solution, sodium alginate solution, or polylactide solution, and ZnO‐doped bioglass from CaO‐SiO 2 ‐P 2 O 5 system. The properties of zinc ions were used, which have bactericidal, immune‐stimulating, and tissue‐regenerating functions in the organism. The effects of the polymer type, granulation, and bioglass amount, as well as the amount of solvent on composite microstructure, were studied. SEM ‐ EDS technique was used to visualize and describe the surface results occurring after incubation of composite in the Simulated Body Fluid ( SBF ). The selected method of preparation, used substrates, and the process conditions resulted in porous composites of the open, connected pore structure. It was proved that composite microstructure may be controlled by the appropriately selected amount of bioglass in relation to the polymer and its appropriate grain sizes. The morphology of the obtained composites is also affected by the amount of the solvent in lyophilizated dispersions. It was proved that bioactivity in composite material is induced by bioglass because after SBF incubation the surface layer is enriched with Ca and P, what may lead to a gradual formation of apatite layer. The obtained results enabled selection of the composites for further in vitro studies concerning cytotoxicity and antibacterial activity.