Development of a robust supramolecular method to prepare well-defined nanofibrils from conjugated molecules

Tian, Liangfei; Szilluweit, Ruth; Marty, Roman; Bertschi, Louis; Zerson, Mario; Spitzner, Eike-Christian; Magerle, R.; Frauenrath, Holger

doi:10.1039/c2sc00977c

Cited by 51 publications

(65 citation statements)

References 67 publications

(68 reference statements)

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“…In this way, the versatile properties of different types of silk materials are precisely tailored according to their function [11][12][13] . Inspired by this example of nature's design principles, the selective formation of onedimensional nanostructures from b-sheet-forming oligopeptides and oligopeptide-modified polymers has been extensively investigated [14][15][16][17][18][19][20][21][22][23][24][25][26][27][28] . However, the thermomechanical properties of the corresponding bulk materials have rarely been studied in much detail [29][30][31] .…”

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confidence: 99%

A toolbox of oligopeptide-modified polymers for tailored elastomers

Croisier

Schweizer

et al. 2014

Nat Commun

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Biomaterials are constructed from limited sets of building blocks but exhibit extraordinary and versatile properties, because hierarchical structure formation lets them employ identical supramolecular motifs for different purposes. Here we exert a similar degree of structural control in synthetic supramolecular elastomers and thus tailor them for a broad range of thermomechanical properties. We show that oligopeptide-terminated polymers selectively self-assemble into small aggregates or nanofibrils, depending on the length of the oligopeptides. This process is self-sorting if differently long oligopeptides are combined so that different nanostructures coexist in bulk mixtures. Blends of polymers with oligopeptides matching in length furnish reinforced elastomers that exhibit shear moduli one order of magnitude higher than the parent polymers. By contrast, novel interpenetrating supramolecular networks that display excellent vibration damping properties are obtained from blends comprising non-matching oligopeptides or unmodified polymers. Hence, blends of oligopeptide-modified polymers constitute a toolbox for tailored elastomers with versatile properties.

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confidence: 99%

A toolbox of oligopeptide-modified polymers for tailored elastomers

Croisier

Schweizer

et al. 2014

Nat Commun

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“…An amino acid sequence is chosen that will preferentially form β ‐sheets (in this case, parallel β ‐sheets) with stabilizing hydrogen bonds being formed between adjacent chains. The final feature is a terminal end group (green) that further directs nanostructure formation through hydrogen bonding NHAc and oligopeptide motifs as well as π‐stacking Fmoc units . This molecular architecture acts as a “supramolecular synthon” where the individual segments of a single molecule are specifically designed to cooperatively direct the formation of well‐defined nanostructures .…”

Section: Approaches To Isolable Collections Of Single Pda Chainsmentioning

confidence: 99%

Polydiacetylene‐Peptide 1D Nanomaterials

Diegelmann

Tovar

2013

Macromol. Rapid Commun.

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Polydiacetylenes have received intense attention on account of their well-established chromic alterations that are detectable often by the naked eye, making them ideal for a variety of applications such as biosensory materials. These polymers have been fabricated in a variety of materials platforms including 3D crystals, 2D monolayers, and 0D spherical vesicles; however, 1D morphologies that might be useful for directional energy migration are less common. This article describes the development and current research efforts of protein-based 1D nanowire-like supramolecular assemblies with embedded polydiacetylenes.

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“…Previous studies have shown that peptides with as few as four amino acid residues can assemble into fibrous gels that mimic the structure of soft tissues, giving rise to hybrid materials that are viable for in vivo applications . Peptide‐hybrids containing conjugated thiophene or phenylene oligomers have been analyzed and shown to form canonical structures based upon the amino acid sequence of the peptide, resulting in fibrillar structures with unique optical properties . Composites containing peptide assemblies and CPs such as polyacetylene and poly(3,4‐ethylenedioxythiophene) (PEDOT) derivatives have also been reported, but bulk hydrogel structure, mechanical and electrical properties have yet to be investigated in detail.…”

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confidence: 99%

Peptide‐Thiophene Hybrids as Self‐Assembling Conductive Hydrogels

James

Jenkins

Murphy

2019

Macro Materials & Eng

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A bottom‐up approach is taken to confer multidimensional structure to conductive polymers by attaching thiophene monomers to peptides predicted to self‐assemble into a biomimetic, fibrous nanostructure. A library of 12 peptides containing covalently attached thiophene monomers are synthesized. Peptide sequences capable of robust self‐assembly and hydrogel formation in aqueous media are further polymerized in situ and the physical and electrical properties are characterized. The resulting hybrid materials have conductivities in the range of 10−2 to 10−3 S cm−1 and possess moduli in the range of several tissue types, making them potential candidates for use in tissue engineering and bioelectronic applications.

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Development of a robust supramolecular method to prepare well-defined nanofibrils from conjugated molecules

Cited by 51 publications

References 67 publications

A toolbox of oligopeptide-modified polymers for tailored elastomers

A toolbox of oligopeptide-modified polymers for tailored elastomers

Polydiacetylene‐Peptide 1D Nanomaterials

Peptide‐Thiophene Hybrids as Self‐Assembling Conductive Hydrogels

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