Preparation of bioactive glass ceramic nanoparticles by combination of sol–gel and coprecipitation method

“…thin films or particles, are highly porous exhibiting a high specific surface area [10,40,46]. Recent work on fabricating bioactive silicate glass nanoparticles by sol-gel process has been carried out by Hong et al [47]. In their research, nanoscale bioactive glass particles were obtained by the combination of two steps; sol-gel route and coprecipitation method, wherein the mixture of precursors was hydrolyzed in acidic environment and condensed in alkaline condition separately, and then followed by a freeze-drying process.…”

“…In their research, nanoscale bioactive glass particles were obtained by the combination of two steps; sol-gel route and coprecipitation method, wherein the mixture of precursors was hydrolyzed in acidic environment and condensed in alkaline condition separately, and then followed by a freeze-drying process. A schematic diagram about the improved sol-gel synthesis process developed by Hong et al [42,47] is presented in Figure 1. The morphology and size of bioactive glass nanoparticles could be tailored by varying the production conditions and the feeding ratio of reagents [48,49].…”

Polymer/bioactive glass nanocomposites for biomedical applications: A review

“…thin films or particles, are highly porous exhibiting a high specific surface area [10,40,46]. Recent work on fabricating bioactive silicate glass nanoparticles by sol-gel process has been carried out by Hong et al [47]. In their research, nanoscale bioactive glass particles were obtained by the combination of two steps; sol-gel route and coprecipitation method, wherein the mixture of precursors was hydrolyzed in acidic environment and condensed in alkaline condition separately, and then followed by a freeze-drying process.…”

“…In their research, nanoscale bioactive glass particles were obtained by the combination of two steps; sol-gel route and coprecipitation method, wherein the mixture of precursors was hydrolyzed in acidic environment and condensed in alkaline condition separately, and then followed by a freeze-drying process. A schematic diagram about the improved sol-gel synthesis process developed by Hong et al [42,47] is presented in Figure 1. The morphology and size of bioactive glass nanoparticles could be tailored by varying the production conditions and the feeding ratio of reagents [48,49].…”

Polymer/bioactive glass nanocomposites for biomedical applications: A review

“…Several groups have attempted to incorporate calcium into silica nanoparticles by using a two-step sol-gel process in which precursors of silica and calcium (TEOS and calcium nitrate respectively) are hydrolysed in an acidic solution before gelation under alkaline conditions [24][25][26][27][28]. While EDX data showed calcium was present in the particles [25] and they induced HCA formation in simulated body fluid (SBF), little or no quantitative analysis was performed on the final elemental composition.…”

“…However, despite being spherical and dispersed, the resulting particles did not show a homogeneous size distribution even after optimisation of the polymer:TEOS ratio. Some papers have attempted to improve the dispersion or shape of the nanoparticles by use of a surfactant [25,28]. However, this can inhibit calcium diffusion, therefore limiting the amount of calcium that enters the glass [1].…”

Controlling particle size in the Stöber process and incorporation of calcium

“…The sol-gel method which was an alternative route proposed for bioactive glass synthesis by Li et al [14] has several advantages and minimizes the limitations of the melt-quenching route. The method has better versatility compared to the melt-quenching technique and requires much lower processing temperatures [15][16][17][18]. The sol-gel bioactive glasses have nano-porosity which results in better cellular response and a better surface area hence better biodissolution.…”

Sol–gel synthesis and in vitro bioactivity of glass–ceramics in SiO2–CaO–Na2O–P2O5 system