Publications

With the aim of healing challenging skin wounds, electro-responsive click-hydrogels made of hyaluronic acid (clickHA) crosslinked with a modified polyethylene glycol precursor (PEG) were prepared by semi- interpenetrating a conducting polymer, poly(hydroxymethyl-3,4-ethylenedioxythiophene) (PEDOT-MeOH) by oxidative polymerization. The porosity and pore size of the mixed hydrogel, clickHA/PEDOT-MeOH, were both higher than those determined for the hydrogel without PEDOT-MeOH, while a honeycomb-like morphology with PEDOT-MeOH covering the pore walls was observed. Although such PEDOT-MeOH-induced changes did not influence the water absorption capacity of clickHA, they drastically affected the mechanical and electrochemical behavior. More specifically, the semi-interpenetration of PEDOT-MeOH into clickHA resulted in an increase of the Young's modulus, the compressive strength and, especially, the electrochemical activity. The biocompatibility and the potential for skin regeneration of clickHA/PEDOT-MeOH were preliminary assessed using viability and wound-healing assays with epithelial cells. Not only is the conducting hydrogel formulation biocompatible, but also promotes efficient cell migration by electrostimulation using a small voltage (0.5 V) for a short time (15 min). Thus, in just 1 h the wound gap was repaired, and a homogeneous monolayer of migrated cells was formed.

JTD Keywords: 4-ethylenedioxythiophene, Car, Click hydrogel, Conducting polymer, Hyaluronic acid, Poly(3, Proliferation, Rational design, Scaffold, Skin, Wound dressing

The properties of thiol-yne click polyethylene glycol (PEG)-based hydrogels, which can be tuned by controlling the cis and trans stereochemistry through the gelation conditions, have been investigated at the micro- and nanoscale using optomechanics, atomistic molecular dynamics (MD) simulations, and nanoindentation. Optomechanical measurements on thin films and computer MD simulations have shown that the trans hydrogel is less porous than the cis hydrogel, which is in agreement with both the swelling behavior and the pore size determined for macroscopic 3D hydrogel samples. On the other hand, results from optomechanical measurements using both static and dynamic modes, as well as nanoindentation profiles obtained for thin films adhered to glass substrates, reflect that the trans hydrogel is stiffer than the cis one. Overall, despite the few drawbacks of the techniques employed in this work, from a qualitative point of view, the properties of click PEG-based hydrogels at the micro- and nanoscale follow a behavior similar to that found for 3D macroscopic samples. Considering the wide range of mechanical properties of human tissues (e.g., Young's modulus ranges from 0.1 kPa to many tens of MPa) and the extensive use of hydrogels in applications such as tissue regeneration and tissue-specific drug delivery, the availability of a hydrogel with tunable properties opens the door to targeted biomedicine.

JTD Keywords: Algorithm, Elastic modulu, Ewal, Injectable hydrogels, Molecular dynamics, Molecular-dynamics, Nanoindentation, Optomechanical sensors, Polyethylene glycol hydrogels, Surface stress, Thiol-yneclick hydrogels