par Ding, Peng;Wei, Qianqian;Tian, Ning;Ding, Xiaoyue;Wang, Ling;Wang, Bing;Okoro, Oseweuba 
;Shavandi, Amin ;Nie, Lei
Référence Biomedical Materials (Bristol), 18, 1, page (015006)
Publication Publié, 2022-11-01
;Shavandi, Amin ;Nie, LeiRéférence Biomedical Materials (Bristol), 18, 1, page (015006)
Publication Publié, 2022-11-01
Article révisé par les pairs
| Résumé : | Abstract The enzymatically crosslinked hydrogel could replicate the cellular microenvironment for biomedical applications. In the present study, to improve the cytocompatibility of chitosan (CS), sialic acid (SA) was introduced to CS to synthesize sialylated CS (CS-SA), and the tyramine (TA) was grafted to gelatin (G) to obtain TA modified gelatin (G-TA). The successful synthesis of CS-SA and G-TA was confirmed using 1 H NMR and UV–Vis absorption spectra. The interpenetrating polymer networks G-TA/CS-SA (GC) hydrogel was then fabricated via blending G-TA and CS-SA solutions and crosslinked using horseradish peroxidase. The storage modulus (G′) of the fabricated GC hydrogels with different ratios of G-TA/CS-SA greatly varied during the formation and strain of hydrogels. With the increase of CS-SA concentration from 0% to 2%, the storage modulus of GC hydrogels was also observed to decrease from 1500 Pa to 101 Pa; the water uptake capacity of GC hydrogels increased from 1000% to 4500%. Additionally, the cell counting kit-8 and fluorescent images demonstrated the excellent cytocompatibility of GC hydrogels after culturing with NIH 3T3 cells. The obtained results indicated that the fabricated GC hydrogels might have potential in biomedical fields, such as wound dressing. |
