Tuning hydrogel properties with sequence-defined, non-natural peptoid crosslinkers

The native extracellular matrix (ECM) is composed of hierarchically structured biopolymers containing precise monomer sequences and chain shapes to yield bioactivity. Recapitulating this structure in synthetic hydrogels is of particular interest for tissue engineering and in vitro disease models to...

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Published in:Journal of materials chemistry. B, Materials for biology and medicine Materials for biology and medicine, 2020-08, Vol.8 (31), p.6925-6933
Main Authors: Morton, Logan D, Hillsley, Alexander, Austin, Mariah J, Rosales, Adrianne M
Format: Article
Language:English
Subjects:
Amino Acid Sequence
Biological activity
Biopolymers
Bulk modulus
Cell culture
Cell Survival - drug effects
Chains
Crosslinking
Extracellular matrix
Fibroblasts
Fibroblasts - cytology
Fibroblasts - drug effects
Humans
Hydrogels
Hydrogels - chemistry
Microenvironments
Peptides
Peptides - chemistry
Peptides - pharmacology
Polyethylene glycol
Polyethylene Glycols - chemistry
Protein Conformation, alpha-Helical
Storage modulus
Structural hierarchy
Substitutes
Tissue engineering
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Summary:The native extracellular matrix (ECM) is composed of hierarchically structured biopolymers containing precise monomer sequences and chain shapes to yield bioactivity. Recapitulating this structure in synthetic hydrogels is of particular interest for tissue engineering and in vitro disease models to accurately mimic biological microenvironments. However, despite extensive research on hydrogels, it remains a challenge to recapitulate the hierarchical structure of native ECM with completely synthetic hydrogel platforms. Toward this end, this work presents a synthetic hydrogel system using commercially available poly(ethylene glycol) macromers with sequence-defined poly( N -substituted glycines) (peptoids) as crosslinkers. We demonstrate that bulk hydrogel mechanics, specifically as shear storage modulus, can be controlled by altering peptoid sequence and structure. Notably, the helical peptoid sequence investigated here increases the storage modulus of the resulting hydrogels with increasing helical content and chain length, in a fashion similar to helical peptide-crosslinked hydrogels. In addition, the resulting hydrogels are shown to be hydrolytically and enzymatically stable due to the N -substituted peptidomimetic backbone of the crosslinkers. We further demonstrate the potential utility of these peptoid-crosslinked hydrogels as a viable cell culture platform using seeded human dermal fibroblasts in comparison to peptide-crosslinked hydrogels as a control. Taken together, our system offers a strategy toward ECM mimics that replicate the hierarchy of biological matrices with completely synthetic, sequence-defined molecules. Helical peptoid crosslinkers confer tunable mechanical properties and enzymatic stability to hydrogels for cell culture.
ISSN:2050-750X
2050-7518
DOI:10.1039/d0tb00683a