Tunable physical and mechanical properties of gelatin hydrogel after transglutaminase crosslinking on two gelatin types

The crosslinking and related gel properties of 3 wt% gelatin (type-A and type-B) catalyzed by microbial transglutaminase (MTG, dose of 0–20 U/g gelatin) have been investigated. A MTG-depended increase in the molecular weight and mean diameter of both gelatins was observed, where type-A presented a higher crosslinking efficiency than type-B due to more acyl donors of the former. As MTG concentration increased, the surface hydrophobicity and thermal stability of type-A gelatin increased. Textural profile analysis (TPA) of type-A gelatin hydrogel showed a decrease in hardness and slight increase in springiness, while type-B gelatin gel was not affected generally. Rheological measurements confirmed the melting point of type-A gelatin hydrogel continually increased until the disappearance of gel thermo-reversibility at higher MTG levels (≥12 U/g gelatin), while type-B gelatin hydrogel always showed a sol-gel transition, suggesting that the gel performance was depended on the dominance of whether physical crosslinking or chemical crosslinking. Scanning electron microscope (SEM) results showed that the network structure of the type-A gelatin became more irregular as MTG increasing which indicated that introducing additional covalent cross-links within or between gelatin chains had a profound influence on gel's network structure, closely associated with the gel properties mentioned above. In summary, the superiority of type-A in MTG-crosslinking efficiency than type-B, can be used to modulate the physical and mechanical properties of gelatin hydrogel, governing by the combing of weak physical crosslinking and strong covalent crosslinking, which will be suitable for numerous industrial applications.