Controlling network topology and mechanical properties of co‐assembling peptide hydrogels

Boothroyd, Stephen; Saiani, Alberto; Miller, Aline F.

doi:10.1002/bip.22435

Cited by 40 publications

(40 citation statements)

References 48 publications

(67 reference statements)

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“…111 Peptide cross linking was assessed by SAXS, TEM and FTIR and interestingly, the storage modulus G 0 of the mixed peptide system increased up to 30 times relative to a hydrogel of the octapeptide (Table 2), thus confirming the utility of the method to generate stiffer hydrogels. The longer peptide was conceived with the idea of favouring incorporation within two separate b-sheet fibrils of the octapeptide, thus forming a controllable number of cross-links/branch points in the fibrillar network.…”

Section: -Nh 2 O Ac-(fkfe) 3 -Nh 2 Omentioning

confidence: 72%

Structure–mechanical property correlations of hydrogel forming β-sheet peptides

et al. 2016

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Peptide based hydrogels have received much attention due to their potential biomedical applications. The majority of the gel forming peptides present a β-sheet motif that is composed of alternating hydrophobic/hydrophilic amino acids. Furthermore, structural characterization of the assembly of these β-sheet peptides has been refined recently. However, the relationship between peptide residue composition, molecular structure and the mechanical properties of the resulting hydrogel is not entirely understood. In this review, an analysis of the structural features of different β-sheet peptide hydrogels and their mechanical properties is discussed, in order to provide further insight on the molecular features that are relevant for the design of effective β-peptide hydrogels.

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Section: -Nh 2 O Ac-(fkfe) 3 -Nh 2 Omentioning

confidence: 72%

Structure–mechanical property correlations of hydrogel forming β-sheet peptides

et al. 2016

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“…S3. As can be seen from the figure, the storage modulus G′ of the three gels are always greater than the loss modulus G′′ with the angular frequency gradually increased from 0.1 rad ⋅ s -1 to 628.0 rad ⋅ s -1 , indicating that there has been no phase transition during the test and the system is a true gel 52. Additionally, the values of G′ and G′′ do not change significantly and after removing the shear force.…”

mentioning

confidence: 83%

A novel calix[4]arene-based dimeric-cholesteryl derivative: synthesis, gelation and unusual properties

Liu

Chen

et al. 2015

New J. Chem.

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A calix [4]arene-based dimeric-cholesteryl derivative with naphthalene in the linkers (C2N2C) was designed and synthesized. The gelation behaviors of the compound in 36 liquids were evaluated. It was demonstrated that C2N2C could gel 16 of the liquids tested, which include both polar and apolar liquids. SEM and AFM studies revealed that the morphologies of the gel networks are dependent on the concentrations of C2N2C and the nature of the liquids under study. Importantly, rheological studies manifested that the gel of the compound in benzene possesses sensitive, fast and fully reversible thixotropic property. More importantly, the T gel of the C2N2C/benzene gel could be at least more than 60 degrees higher than the boiling point of benzene when the gelator concentration is greater than 6% (w/v), a result never reported before. CD measurements revealed the chiral nature of the assemblies of the gel networks. Further investigation by AFM measurements confirmed the right-hand helical structures of the gel networks of C2N2C/benzene gel. As anticipated, hydrogen bonding and π-π stacking are two main driving forces for the formation of the gels.

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“…22,[29][30][31][32] Another example that improved peptide gel strength and systematically controlled the mechanical properties of peptide hydrogels, was based on mixing various quantities of self-assembling ioniccomplementary peptide FEFEFKFK (FEKII8) and its double length counterpart FEFEFKFK-GG-FKFKFEFE (FEKII18). 20 While the hydrogels obtained in water solutions show a G 0 for FEKII8 of 80 AE 5 Pa, when FEKII18 is added to FEKII8 network an increase of G 0 of 30 times is achieved. However, the reached stiffness, while appropriate for cells growing on soft tissues would not be appropriate for other applications in tissue engineering, such as cartilage or bone scaffolds.…”

Section: Introductionmentioning

confidence: 97%

“…An alternative strategy to tune properties of the hydrogel is to use multicomponent systems, where the mixed self‐assembling peptides can differ with point amino acid substitution, or can be unrelated . Another example that improved peptide gel strength and systematically controlled the mechanical properties of peptide hydrogels, was based on mixing various quantities of self‐assembling ionic‐complementary peptide FEFEFKFK (FEKII8) and its double length counterpart FEFEFKFK‐GG‐FKFKFEFE (FEKII18) . While the hydrogels obtained in water solutions show a G′ for FEKII8 of 80 ± 5 Pa, when FEKII18 is added to FEKII8 network an increase of G′ of 30 times is achieved.…”

Section: Introductionmentioning

confidence: 99%

“…Several studies have shown peptide hydrogel systems with tuneable stiffness, where tuning is mainly achieved by varying peptide concentrations in the hydrogels. [19][20][21] Some attempts to change hydrogel stiffness by varying amino acid composition in peptide amphiphilic systems has been explored, highlighting the key role of hydrophobic interactions in gel stiffness. 22,23 A similar effect on gel strength can be obtained by varying salt concentration, when charged amino acids are present in the peptide sequence.…”

Section: Introductionmentioning

confidence: 99%

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Tuning of hydrogel stiffness using a two‐component peptide system for mammalian cell culture

Scelsi

Bochicchio

Smith

et al. 2018

J Biomedical Materials Res

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Self‐assembling peptide hydrogels (SAPHs) represent emerging cell cultures systems in several biomedical applications. The advantages of SAPHs are mainly ascribed to the absence of toxic chemical cross‐linkers, the presence of ECM‐like fibrillar structures and the possibility to produce hydrogels with a large range of different mechanical properties. We will present a two‐component peptide system with tuneable mechanical properties, consisting of a small pentapeptide (SFFSF‐NH 2 , SA5N) that acts as a gelator and a larger 21‐mer peptide (SFFSF‐GVPGVGVPGVG‐SFFSF, SA21) designed as a physical cross‐linker. The hydrogels formed by different mixtures of the two peptides are made up mainly of antiparallel β‐sheet nanofibers entangling in an intricate network. The effect of the addition of SA21 on the morphology of the hydrogels was investigated by atomic force microscopy and transmission electron microscopy and correlated to the mechanical properties of the hydrogel. Finally, the biocompatibility of the hydrogels using 2D cell cultures was tested. © 2018 The Authors. journal Of Biomedical Materials Research Part A Published By Wiley Periodicals, Inc. J Biomed Mater Res Part A: 107A: 535–544, 2019.

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Controlling network topology and mechanical properties of co‐assembling peptide hydrogels

Cited by 40 publications

References 48 publications

Structure–mechanical property correlations of hydrogel forming β-sheet peptides

Structure–mechanical property correlations of hydrogel forming β-sheet peptides

A novel calix[4]arene-based dimeric-cholesteryl derivative: synthesis, gelation and unusual properties

Tuning of hydrogel stiffness using a two‐component peptide system for mammalian cell culture

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