preparation and evaluation a novel hydrogel scaffold contained bioactiveglass nano whisker(bgnw) for osteogenic differentiation of human mesenchymal stem cells(hmscs)

Aim and background: useing hydrogels as an alternative strategy for repairing bone defects has received great attention in bone tissue engineering. in this study, hydrogel scaffold based on collagen, gelatin, and glutaraldehyde was combined with bioactive glass nanowhiskers (bgnw) to differentiate human mesenchymal stem cells (hmscs) into the osteogenic lineage and inducing biomineralization. pure gel-glu-col and bioactive glass nanowhiskers were used as control throughout the paper. methods: chemical, physical and morphological characteristics of the nanocomposite scaffold were assessed meticulously using fourier transform infrared spectroscopy (ftir), x-ray diffraction (xrd), porosity measurement, water uptake ability, tensile test, and scanning electron microscopy (sem). to determine the cytotoxicity and cell viability of the hydrogel, mtt assay and acridine orange (ao) staining were performed. hmscs seeded on gel-glu-col/bgnw were then incubated with osteogenic differentiation media for 14 days. biomineralization assays (alkaline phosphatase (alp) activity, calcium content assay, von kossa, and alizarin red staining) were carried out, and osteogenic genes and markers were examined using real time-pcr and immunocytochemistry. results and discussion: results showed that the components of the hydrogel were properly integrated. the mechanical property of hydrogel was enhanced following the addition of bgnw. cell viability assays confirmed the biocompatibility of the scaffold and increasing the proliferation after incorporating bgnw into pure ge1-glu-col. our nanocomposite maintained an enhanced ability of biomineralization as compared to its pure counterparts. molecular investigations revealed an elevated level of osteogenic markers as compared to ge1-glu-col and bgnw. all in all, gel-glu-col/bgnw seems to be a potential candidate for the regeneration of bone tissue. conclusion: in conclusion, our results revealed that these biocompatible hydrogel nanoscaffolds have the necessary characteristics for bone tissue engineering purposes