Polysaccharide-based bionanocomposite hydrogels with functional nanomaterials were used in biomed- ical applications. Self-organization of xanthan gum and chitosan in the presence of iron oxide magnetic nanoparticles ...Polysaccharide-based bionanocomposite hydrogels with functional nanomaterials were used in biomed- ical applications. Self-organization of xanthan gum and chitosan in the presence of iron oxide magnetic nanoparticles (Fe304 MNPs) allowed us to form magnetically responsive polyelectrolyte complex hydro- gels (MPECHs) via insitu ionic complexation using D-(+)-glucuronic acid ^-lactone as a green acidifying agent. Characterization confirmed the successful formation of (and structural interactions within) the MPECH and good porous structure. The rheological behavior and compressive properties of the PECH and MPECH were measured. The results indicated that the incorporation of Fe304 MNPs into the PECH greatly improved mechanical properties and storage modulus (G'). In vitro cell culture of NIH3T3 fibroblasts on MPECHs showed improvements in cell proliferation and adhesion in an external magnetic field relative to the pristine PECH. The results showed that the newly developed MPECH could potentially be used as a magnetically stimulated system in tissue engineering applications.展开更多
基金fully supported by the 2017 Yeungnam University Research Grant
文摘Polysaccharide-based bionanocomposite hydrogels with functional nanomaterials were used in biomed- ical applications. Self-organization of xanthan gum and chitosan in the presence of iron oxide magnetic nanoparticles (Fe304 MNPs) allowed us to form magnetically responsive polyelectrolyte complex hydro- gels (MPECHs) via insitu ionic complexation using D-(+)-glucuronic acid ^-lactone as a green acidifying agent. Characterization confirmed the successful formation of (and structural interactions within) the MPECH and good porous structure. The rheological behavior and compressive properties of the PECH and MPECH were measured. The results indicated that the incorporation of Fe304 MNPs into the PECH greatly improved mechanical properties and storage modulus (G'). In vitro cell culture of NIH3T3 fibroblasts on MPECHs showed improvements in cell proliferation and adhesion in an external magnetic field relative to the pristine PECH. The results showed that the newly developed MPECH could potentially be used as a magnetically stimulated system in tissue engineering applications.
