Amino-acids-functionalized M13-assisted synthesis of silver and silver sulfide nanoparticles

“…[54,64] The use of chiral biomolecules including amino acids, peptides, protein or DNA, etc., was invaluable for inducing and manipulating chiroptical activity in metal nanomaterials, in which the chiral interface was not well understood for the complexity of molecule−NPs interaction. [3,[71][72][73][74] Generally, the heterogenous metal structures with strong Plasmonic resonance facilitate to inducement of strong chiroptical signals. [61,75,76] It is reported that complex interactions between D-peptides and Au NPs lead to a chiral restructuring of peptides and proteolytic cleavage of D-peptides via gold-mediated inversion of peptide chirality.…”

Biomimetic Chiral Nanomaterials with Selective Catalysis Activity

“…[54,64] The use of chiral biomolecules including amino acids, peptides, protein or DNA, etc., was invaluable for inducing and manipulating chiroptical activity in metal nanomaterials, in which the chiral interface was not well understood for the complexity of molecule−NPs interaction. [3,[71][72][73][74] Generally, the heterogenous metal structures with strong Plasmonic resonance facilitate to inducement of strong chiroptical signals. [61,75,76] It is reported that complex interactions between D-peptides and Au NPs lead to a chiral restructuring of peptides and proteolytic cleavage of D-peptides via gold-mediated inversion of peptide chirality.…”

Biomimetic Chiral Nanomaterials with Selective Catalysis Activity

A temperature-insensitive silver nanostructures@graphene foam for high accuracy and full range human health monitoring

A cubic Cu₂O@Ag bioprobe for label-free SERS classification of hepatic fibrosis and hepatocellular carcinoma