Design, Synthesis, Assembly, and Engineering of Peptoid Nanosheets

Abstract: Two-dimensional (2D) atomically defined organic nanomaterials are an important material class with broad applications. However, few general synthetic methods exist to produce such materials in high yields and to precisely functionalize them. One strategy to form ordered 2D organic nanomaterials is through the supramolecular assembly of sequence-defined synthetic polymers. Peptoids, one such class of polymer, are designable bioinspired heteropolymers whose main-chain length and monomer sequence can be precisely… Show more

“…4a). 15 By XRD it was observed that the p-chloro substitution increases the nanosheet thickness to 3.25 nm, which decreases to 2.97 nm upon irradiation (Fig. 4a), an observation consistent with the liberation of chlorine and formation of a biphenyl bridge in the nanosheet interior.…”

“…1a and b). 15 Peptoid nanosheets have been shown to act as robust scaffolds capable of displaying sequence-defined loops on their surface, mimicking the hierarchical structure of proteins. 17 These engineered nanosheets can perform specific functions such as the molecular recognition of proteins, 17 or templating the growth of inorganic materials.…”

Improved chemical and mechanical stability of peptoid nanosheets by photo-crosslinking the hydrophobic core

“…4a). 15 By XRD it was observed that the p-chloro substitution increases the nanosheet thickness to 3.25 nm, which decreases to 2.97 nm upon irradiation (Fig. 4a), an observation consistent with the liberation of chlorine and formation of a biphenyl bridge in the nanosheet interior.…”

“…1a and b). 15 Peptoid nanosheets have been shown to act as robust scaffolds capable of displaying sequence-defined loops on their surface, mimicking the hierarchical structure of proteins. 17 These engineered nanosheets can perform specific functions such as the molecular recognition of proteins, 17 or templating the growth of inorganic materials.…”

Improved chemical and mechanical stability of peptoid nanosheets by photo-crosslinking the hydrophobic core

“…As a result of these structural attributes, polypeptoids tend to self-associate or aggregate in solution or at interfaces. [88,119,120] Understanding their supramolecular assemblies in solution or at the interface will be of fundamental importance and will have implications for practical uses of these polymers in solution-based applications. With advances in synthesis, understanding of how molecular interactions encoded in the N-substituent structures and monomer sequences impact the nanoscale and mesoscale assemblies of polypeptoids will be of significant interest in the rational design of polypeptoid polymers for targeted applications.…”

“…As a result, the global conformations of polypeptoids are strongly dependent on the N-substituent structures, giving rise to random coils or well-defined secondary structures [eg, polyproline I (PPI) helix [1][2][3][4][5][6] and R-sheets] [7][8][9][10][11][12] that are reminiscent of those of polypeptides. The polypeptoid backbone containing tertiary amide linkages is highly polar and hydrophilic.…”

“…The polypeptoid backbone containing tertiary amide linkages is highly polar and hydrophilic. The physicochemical properties of polypeptoids can be tailored by the N-substituent structures, enabling control over the hydrophilicity and lipophilicity balance (HLB), charge characteristics, [13,14] backbone conformation, [1][2][3][4][5][6][7][8][9][10][11][12] solubility, [15][16][17][18][19][20] thermal and crystallization properties of the polypeptoids. [21][22][23][24] Without extensive hydrogen bonding, polypeptoids are thermally processable similar to conventional thermoplastics, [20][21][22][23][24] whereas polypeptides undergo thermal degradation before they can be melt-processed due to the extensive hydrogen bonding interactions.…”

Polypeptoid polymers: Synthesis, characterization, and properties

Sequence‐Controlled Peptoid Polymers: Bridging the Gap between Biology and Synthetic Polymers