Peng Yang scite author profile

2D nanofilms assembled by pure protein with a macroscopic area and multiple functions can be directly formed at the air/water interface or at the solid surface at a timescale of several minutes. The multifunctionality of the nanofilm coating is demonstrated by both top-down and bottom-up micro-/nanoscale interfacial engineering, including surface modification, all-water-based photo/electron-beam lithography, and electroless deposition.

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Amyloid‐Like Protein Aggregates: A New Class of Bioinspired Materials Merging an Interfacial Anchor with Antifouling

Tian

et al. 2020

Advanced Materials

136

149

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Surfaces that resist nonspecific protein adsorption in a complex biological milieu are required for a variety of applications. However, few strategies can achieve a robust antifouling coating on a surface in an easy and reliable way, regardless of material type, morphology, and shape. Herein, the preparation of an antifouling coating by one‐step aqueous supramolecular assembly of bovine serum albumin (BSA) is reported. Based on fast amyloid‐like protein aggregation through the rapid reduction of the intramolecular disulfide bonds of BSA by tris(2‐carboxyethyl)phosphine, a dense proteinaceous nanofilm with controllable thickness (≈130 nm) can be covered on virtually arbitrary material surfaces in tens of minutes by a simple dipping or spraying. The nanofilm shows strong stability and adhesion with the underlying substrate, exhibiting excellent resistance to the nonspecific adsorption of a broad‐spectrum of contaminants including proteins, serum, cell lysate, cells, and microbes, etc. In vitro and in vivo experiments show that the nanofilm can prevent the adhesion of microorganisms and the formation of biofilm. Compared with native BSA, the proteinaceous nanofilm coating exposes a variety of functional groups on the surface, which have more‐stable adhesion with the surface and can maintain the antifouling in harsh conditions including under ultrasound, surfactants, organic solvents, and enzymatic digestion.

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Vesicles in electric fields: Some novel aspects of membrane behavior

et al. 2009

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An Environmentally Benign Antimicrobial Coating Based on a Protein Supramolecular Assembly

Liu

et al. 2016

ACS Appl. Mater. Interfaces

180

135

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The use of antimicrobial materials, for example, silver nanoparticles, has been a cause for concern because they often exert an adverse effect on environmental and safety during their preparation and use. In this study, we report a class of green antimicrobial coating based on a supramolecular assembly of a protein extracted from daily food, without the addition of any other hazardous agents. It is found that a self-assembled nanofilm by mere hen egg white lysozyme has durable in vitro and in vivo broad-spectrum antimicrobial efficacy against Gram-positive/negative and fungi. Such enhanced antimicrobial capability over native lysozyme is attributed to a synergistic combination of positive charge and hydrophobic amino acid residues enriched on polymeric aggregates in the lysozyme nanofilm. Accompanied with high antimicrobial activity, this protein-based PTL material simultaneously exhibits the integration of multiple functions including antifouling, antibiofilm, blood compatibility, and low cytotoxicity due to the existence of surface hydration effect. Moreover, the bioinspired adhesion mediated by the amyloid structure contained in the nanofilm induces robust transfer and self-adhesion of the material onto virtually arbitrary substrates by a simple one-step aqueous coating or solvent-free printing in 1 min, thereby allowing an ultrafast route into practical implications for surface-functionalized commodity and biomedical devices. Our results demonstrate that the application of pure proteinaceous substance may afford a cost-effective green biomaterial that has high antimicrobial activity and low environmental impact.

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Tuning protein assembly pathways through superfast amyloid-like aggregation

Zuo

et al. 2018

Biomater. Sci.

110

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Amyloid formation of proteins is not only relevant for neurodegenerative diseases, but has recently emerged as a groundbreaking approach in materials science and biotechnology. However, amyloid aggregation of proteins in vitro generally requires a long incubation time under extremely harsh conditions, and the understanding of the structural motif to determine amyloid assembly is extremely limited. Herein we reveal that the integration of three important building blocks in typical globular proteins is crucial for superfast protein amyloid-like assembly including the segment required for high fibrillation propensity, abundant α-helix structures and intramolecular S-S bonds to lock the α-helix. With the reduction of the S-S bond by tris(2-carboxyethyl)phosphine (TCEP), the α-helix was rapidly unlocked from the protein chain, and the resultant unfolded monomer underwent a fast transition to β-sheet-rich amyloid oligomers and protofibrils in minutes, which further assembled into a macroscopic nanofilm at the air/water interface and microparticles in bulk solution, respectively.

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Peng Yang

2D Protein Supramolecular Nanofilm with Exceptionally Large Area and Emergent Functions

Amyloid‐Like Protein Aggregates: A New Class of Bioinspired Materials Merging an Interfacial Anchor with Antifouling

Vesicles in electric fields: Some novel aspects of membrane behavior

An Environmentally Benign Antimicrobial Coating Based on a Protein Supramolecular Assembly

Tuning protein assembly pathways through superfast amyloid-like aggregation

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