Photothermal Core-Shell TiN@Borosilicate Bioglass Nanoparticles: Degradation and Mineralization

doi:10.15541/jim20220742

Abstract

Abstract:

Borosilicate bioglass has attracted extensive attention due to its stable structure and excellent biological activity. However, the rate of its mineralization process is fast in the initial stage and slow in the middle and late stages, which limits the application of borosilicate bioglass. As an auxiliary method, the near-infrared (NIR) laser can accelerate the degradation of bioglass. Therefore, we prepared a core-shell borosilicate bioglass with titanium nitride as the core and bioglass (40SiO₂-20B₂O₃-36CaO-4P₂O₅) as the shell, and used near-infrared laser regulation technology to intervene the mineralization process of the composite bioglass. The experimental results show that the core-shell bioglass exhibits a significant photothermal effect, and the photothermal ability increases with the increases of the doping amount of TiN NPs and the laser power density. During the in vitro immersion, near-infrared laser increased the degradation rate of bioglass. After immersion for 7 d, the contents of calcium and boron in the SBF are increased by 12%-16% and 8%-11%, respectively. Meanwhile, the formation efficiency of hydroxyapatite is significantly improved. Cell proliferation activity test shows that the sample has good biological safety. Therefore, near-infrared light can accelerate the degradation and mineralization of functional core-shell bioactive glass, which is expected to play a regulatory role.

Key words: borosilicate bioactive glass, core-shell structure, photothermal performance, mineralization

CLC Number:

TQ171

WU Rui, ZHANG Minhui, JIN Chenyun, LIN Jian, WANG Deping. Photothermal Core-Shell TiN@Borosilicate Bioglass Nanoparticles: Degradation and Mineralization[J]. Journal of Inorganic Materials, 2023, 38(6): 708-716.

Figures/Tables 10

Fig. 1 Preparation process of core-shell xTiN@58S-20B nanoparticles CTAB: Hexadecyl trimethyl ammonium bromide; TEOS: Tetraethyl orthosilicate; TBB: Tributyl borate

Fig. 2 Degradation of bioglass nanoparticles in vitro with and without laser irradiation

Fig. 3 Micrographs of xTiN@58S-20B (x=0, 0.02, 0.04) with insets showing the corresponding particle size distributions (a1, b1, c1) SEM images; (a2, b2, c2) TEM images; (a3, b3, c3) EDS spectra

Fig. 4 XRD patterns of xTiN@58S-20B (x=0, 0.02, 0.04), with gray shaded parts A, B, and C showing the glass peak areas, while b and c showing the strongest peak area of the TiN NPs

Fig. 5 Temperature rise diagrams of three samples in air with 1064 nm NIR laser at a power density of 1.0 W/cm2 for 60 s, with insets showing the infrared images correspondingly at each time point, X axial representing the radial distance extending to both sides from the sample center, and the Y axial representing the temperature

Fig. 6 Temperature changes of bioglass (a-c) Temperature changes of 58S-20B (a), 0.02TiN@58S-20B (b), 0.04TiN@58S-20B (c) irradiated by 1064 nm NIR laser at different power density (0.38, 0.42, 0.46, 0.50 W/cm2) for 3 min; (d)Temperature versus power density; (e) Heating curves of three samples under 1064 nm laser irradiation (1.0 W/cm2)

Fig. 7 pH changes and ions release of bioglass samples immersed in SBF at 37 ℃ for 7 d (a-c) pH changes within 7 d; (d-f) Ion release profiles of B, Ca, Si on the 7th day

Fig. 8 SEM images of borosilicate samples immersed in SBF for 7 d with insets showing corresponding EDS spectra (a1, b1, c1) Without NIR laser irradiation; (a2, b2, c2) With NIR laser irradiation

Fig. 9 XRD patterns of mineralization products of three samples with and without laser irradiation

Fig. 10 Cell proliferation activity and cell morphology analysis of control, 58S-20B, 0.02TiN@58S-20B, and 0.04TiN@58S-20B (a) CCK-8 analysis; (b) Fluorescent images of cell morphology. Blue indicates the cell nucleus and red indicates the cell cytoskeleton

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