Mechanical Reinforcement of Polymeric Fibers through Peptide Nanotube Incorporation

Rubin, Daniel J.; Nia, Hadi Tavakoli; Desire, Thierry; Nguyen, Peter Q.; Gevelber, Michael; Ortiz, Christine; Joshi, Neel

doi:10.1021/bm4008293

Cited by 29 publications

(39 citation statements)

References 28 publications

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“…This particular DLCP has also been shown to increase the elastic modulus of polylactides when incorporated as the filler component of a composite fiber. 29 While previous attempts at molecular dynamics simulations have given clues regarding the elastic modulus of a DLCP assembly, 31 this study represents the first experimental characterization of the mechanical properties of DLCP fibers. assembling laterally.…”

Section: Dl-cyclic Peptides (Dlcps) Share Certain Characteristics Wimentioning

confidence: 93%

Structural, Nanomechanical, and Computational Characterization of d,l-Cyclic Peptide Assemblies

et al. 2015

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Section: Dl-cyclic Peptides (Dlcps) Share Certain Characteristics Wimentioning

confidence: 93%

Structural, Nanomechanical, and Computational Characterization of d,l-Cyclic Peptide Assemblies

et al. 2015

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“…Recently, aiming at cost‐efficient self‐assembled materials, several groups developed organic‐organic hybrids, where polymers embed self‐assembled organic nanostructures of different shapes and sizes, eg, nanoscale peptide‐based systems. Thus, Gazit et al used peptide nanofibers to act as nano‐fillers in epoxy polymers, resulting in enhanced mechanical properties of the hybrid, and Joshi et al employed peptide nanotubes to reinforce lactic acid fibers . Stupp et al developed composites based on interacting polysaccharide and self‐assembled peptide system, of interest for biomedical applications …”

Section: Introductionmentioning

confidence: 99%

“…Thus, Gazit et al used peptide nanofibers to act as nano-fillers in epoxy polymers, resulting in enhanced mechanical properties of the hybrid, 8 and Joshi et al employed peptide nanotubes to reinforce lactic acid fibers. 9 Stupp et al developed composites based on interacting polysaccharide and self-assembled peptide system, of interest for biomedical applications. 10 Facile solution-phase assembly of polymer/nanostructure hybrids requires soluble components whose structure can be tuned in order to create optimal hybrid morphologies.…”

Section: Introductionmentioning

confidence: 99%

Composites of hydrophilic polymers and organic nanocrystals enable enhanced robustness

Dutta

Sui

Weissman

et al. 2019

Polymers for Advanced Techs

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We describe a new family of composite materials, polymer/organic nanocrystal (ONC) hybrids. These were prepared from soluble ONCs based on perylene diimides (PDI) and water‐soluble polymers (sodium alginate and polyvinyl alcohol). Polymer/ONC films were characterized by optical spectroscopy, electron microscopy, and tensile strength studies. The films show enhanced chemical and mechanical stability due to synergy between the constituents. The hybrid films are stable in both water and organic solvents, unlike the individual components. The ONCs we employed possess nonlinear optical activity (second harmonic generation, SHG); they showed improved photostability (stable SHG under laser light) in the hybrids. Tensile strength enhancement (as high as twofold in the film having just 2.4% ONCs by weight) was observed as revealed by mechanical measurements. Hybrids with aligned ONCs were also prepared using simple extrusion via syringe needle followed by gelation. Employing ONCs in polymeric hybrid materials enables facile fabrication in aqueous media, synergy, chemical, mechanical, and photostability as well as useful photofunction (SHG), introducing a versatile class of composite materials.

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“…Fibers of peptides also demonstrate potential for electronic devices, because they allow for significant downscaling of the sizes of circuit components in comparison with what is possible with traditional inorganic semiconductor technology . Furthermore, self‐assembled peptide fibers might also be applicable in materials science, due to their unique (silk‐like) mechanical properties …”

Section: Introductionmentioning

confidence: 99%

The Physical Properties and Self‐Assembly Potential of the RFFFR Peptide

2016

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The self-assembly of fibers from peptides has attracted a tremendous amount of attention due to its many applications, such as in drug-delivery systems, in tissue engineering, and in electronic devices. Recently, the self-assembly potential of the designer peptide RFFFR has been reported. Here it is experimentally verified that the peptide forms fibers that are entangled and form solid spheres without water inside. Upon dilution below the critical fiber concentration, the fibers untangle and become totally separated prior to dissolution. These structures readily bind thioflavin T, resulting in a characteristic change in fluorescent properties consistent with β-sheet-rich amyloid structures with aromatic/hydrophobic grooves. The circular dichroism spectroscopy data are dominated by a π→π* transition, thus indicating that the fibers are stabilized by π-stacking. Contrary to what was expected, the dissolution of the spheres/fibers results in increasing fluorescence anisotropy over time. This is explained in terms of HomoFRET between phenylalanine residues with a T-shaped π-stacking mode, which was determined in another study to be the dominant mode through atomistic simulations and semiempirical calculations. Kelvin probe force microscopy measurements indicate that the spheres and fibers have a conductivity comparable to that of gold. Hence, these self-assembled structures might be applicable in organic solid-state electronic devices. The dissolution properties of the spheres further suggest that they might be used as drug-delivery systems.

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Mechanical Reinforcement of Polymeric Fibers through Peptide Nanotube Incorporation

Cited by 29 publications

References 28 publications

Structural, Nanomechanical, and Computational Characterization of d,l-Cyclic Peptide Assemblies

Structural, Nanomechanical, and Computational Characterization of d,l-Cyclic Peptide Assemblies

Composites of hydrophilic polymers and organic nanocrystals enable enhanced robustness

The Physical Properties and Self‐Assembly Potential of the RFFFR Peptide

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