Effects of powder type, particle size (5-20 microm; 90-300 microm; 90-710 microm), and type of dissolution medium on the dissolution behavior of bioactive glasses were investigated in vitro using melt-derived 45S5 and sol-gel derived 58S bioactive glass powders. Dissolution studies were performed in simulated body fluid and in alpha-MEM based cell culture medium at 37 degrees C under dynamic conditions (1 Hz) for periods of 30 min, 1, 2, 4, 8, 17, and 22 h. The concentrations of elements dissolved from the glasses were evaluated using inductively coupled plasma analysis. The reacted powders were analyzed for bioactivity using Fourier transform infrared spectrometry to observe the formation of a calcium phosphate layer on the surface. The non-porous surfaces of melt-derived 45S5 glass powders exhibited lower dissolution rates and rate of surface layer formation than 58S gel-glass powders. The rates of dissolution for both types of powders were lower in culture medium, compared to simulated body fluid, and increased as the particle size decreased. Thus, particle size range, glass type, and powder volume fraction can be used as a means to control the release rate of active ions that stimulate the gene expression and cellular response for tissue proliferation and repair.
Bioactive glasses are known to have the ability to regenerate bone, but their use has been restricted mainly to powder, granules, or small monoliths. This work reports on the development of sol-gel foams with potential applications as bone graft implants or as templates for the in vitro synthesis of bone tissue for transplantation. These bioactive foams exhibit a hierarchical structure with interconnected macropores (10-500 microm) and a mesoporous framework typical of gel-glasses (pores of 2-50 nm). The macroporous matrixes were produced through a novel route that comprises foaming of sol-gel systems. Three glass systems were tested to verify the applicability of this manufacturing route, namely SiO(2), SiO(2)-CaO, and SiO(2)-CaO-P(2)O(5). This new class of material combines large pores to support vascularization and 3-D tissue growth with the ability that bioactive materials have to provide bone-bonding and controlled release of ionic biologic stimuli to promote bone cell proliferation by gene activation.
Nature has evolved mechanisms to create a diversity of specialised materials through nanoscale organisation. Inspired by nature, we have designed hybrid materials with highly tailorable properties, which are achieved through careful control of their nanoscale interactions. These novel materials, based on a silicagelatin hybrid system, have the potential to serve as a platform technology for human tissue regeneration. Strong chemical bonds between the inorganic and organic constituents of the hybrid are essential to enable the precise control of mechanical and dissolution properties. Furthermore, hybrid scaffold porosity was found to highly influence mechanical properties, to the extent where scaffolds of particular strength could be specified based on their porosity. We envisage these Submitted to 2 hybrid materials will find a diverse application in both hard and soft tissue regenerating scaffolds.
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