Polymers from renewable resources are attractive for various industrial and biomedical applications owing to their compatibility, degradability, ease of use and availability. Rapid progress in the development of nanotechnology has improved the characteristic features of polymers in composite materials by reinforcing the nanosized particulates during fabrication. In this study, we have attempted to incorporate metal oxide nanoparticles into polymeric nanofibers in order to enhance the overall properties of the composite scaffold. The thermal stability of a TiO nanoparticle-impregnated zein-polydopamine-based nanofibrous scaffold was investigated, and its potential as a suitable wound dressing material was demonstrated. Further, the influence of nanotopographic structure on improved adhesion, proliferation and migration of cells was ascertained through in vitro assays. The constructive results obtained were well corroborated with the in vivo excisional wound healing experiment. Thus, the competence of the prepared nanofibrous scaffold was examined both in vitro and in vivo and demonstrated to be an alternative, cost-effective biomaterial for skin tissue engineering applications.
A biomimetic Zein polydopamine based nanofiber scaffold was fabricated to deliver bone morphogenic protein-2 (BMP-2) peptide conjugated titanium dioxide nanoparticles in a sustained manner for investigating its osteogenic differentiation potential. To prolong its retention time at the target site, BMP-2 peptide has been conjugated to titanium dioxide nanoparticles owing to its high surface to volume ratio. The effect of biochemical cues from BMP-2 peptide and nanotopographical stimulation of electrospun Zein polydopamine nanofiber were examined for its enhanced osteogenic expression of human fetal osteoblast cells. The sustained delivery of bioactive signals, improved cell adhesion, mineralization, and differentiation could be attributed to its highly interconnected nanofibrous matrix with unique material composition. Further, the expression of osteogenic markers revealed that the fabricated nanofibrous scaffold possess better cell-biomaterial interactions. These promising results demonstrate the potential of the composite nanofibrous scaffold as an effective biomaterial substrate for bone regeneration.
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