Disulfide‐Rich Self‐Assembling Peptides Based on Aromatic Amino Acid

Abstract Aromatic residues in assembling peptides play a crucial role in driving peptide self‐assembly through π–π stacking and hydrophobic interactions. Although various aromatic capping groups have been extensively studied, systematic investigations into the effects of single aromatic amino acids in assembling peptides remain limited. In this study, the influence of aromatic‐aromatic interactions on disulfide‐rich assembling peptides is systematically investigated by incorporating three different aromatic amino acids. Their folding propensity, self‐assembling properties, and rheological behaviors are evaluated. These results indicate that different aromatic‐aromatic interactions have a significant effect on self‐assembly abilities, as determined by critical aggregation concentration (CAC) measurements. Furthermore, the biocompatibility of these hydrogels is assessed, and their potential for 3D cell culture is explored. The injectable F1‐ox hydrogel demonstrate excellent biocompatibility for SHED and NIH3T3 cells and exhibit a porous structure that facilitates nutrient and cellular metabolic waste exchange. This work provides new insights into the molecular design of peptide‐based biomaterials, with a focus on the impact of aromatic residues on disulfide‐rich assembling peptides.