A hybrid hydrogel composed of gelatin and gold nanoparticles (GNPs) was designed to evaluate the effect of new bone formation and proves itself to be useful as an implant material for treating defected bone tissues.
A significant problem that affects tissue-engineered electrospun nanofibrous scaffolds is poor infiltration of cells into the three-dimensional (3D) structure. Physical manipulation can enhance cellular infiltration into electrospun scaffolds. The porosity of electrospun nanofibers was highly enlarged by ultrasonication in an aqueous solution. The porosity and related property changes on a series of nanofibers were observed to be dependent on ultrasonication time and energy. To evaluate cell infiltration into the scaffold, fibroblasts were seeded onto these nanofibers and cultured for different lengths of time. The penetration levels of these cells into the scaffold were monitored using confocal lazer scanning microscopy. The cell infiltration potential was greatly increased with regard to an increase in pore size and porosity. These 3D nanofibrous scaffolds fabricated by an ultrasonication process allowed cells to infiltrate easily into the scaffold. This approach shows great promise for design of cell permeable nanofibrous scaffolds for tissue-engineering applications.
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