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A new boronate ester-based crosslinking strategy allows the design of nonswelling and long-term stable dynamic covalent hydrogels.

N LagneauL TerriacPierre TournierJean-Jacques HelesbeuxG ViaultDenis SéraphinB HalgandF LollC GarnierC JonchèreM RivièreArnaud TessierJ LebretonY MaugarsPierre GuihardCatherine Le VisageVianney Delplace
Published in: Biomaterials science (2023)
Dynamic hydrogels are viscoelastic materials that can be designed to be self-healing, malleable, and injectable, making them particularly interesting for a variety of biomedical applications. To design dynamic hydrogels, dynamic covalent crosslinking reactions are attracting increasing attention. However, dynamic covalent hydrogels tend to swell, and often lack stability. Boronate ester-based hydrogels, which result from the dynamic covalent reaction between a phenylboronic acid (PBA) derivative and a diol, are based on stable precursors, and can therefore address these limitations. Yet, boronate ester formation hardly occurs at physiological pH. To produce dynamic covalent hydrogels at physiological pH, we performed a molecular screening of PBA derivatives in association with a variety of diols, using hyaluronic acid as a polymer of interest. The combination of Wulff-type PBA (wPBA) and glucamine stood out as a unique couple to obtain the desired hydrogels. We showed that optimized wPBA/glucamine hydrogels are minimally- to non-swelling, stable long term (over months), tunable in terms of mechanical properties, and cytocompatible. We further characterized their viscoelastic and self-healing properties, highlighting their potential for biomedical applications.
Keyphrases
  • hyaluronic acid
  • drug delivery
  • tissue engineering
  • extracellular matrix
  • drug release
  • wound healing
  • climate change
  • working memory
  • risk assessment
  • mass spectrometry
  • single molecule