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Injectable liposome-containing click hydrogel microparticles for release of macromolecular cargos.

Luisa L PalmesePaige J LeValleyLina PradhanAmanda L ParsonsJohn S OakeyMathew AbrahamSuzanne M D'AddioApril M KloxinYingkai LiangKristi L Kiick
Published in: Soft matter (2024)
Hydrogel microparticles ranging from 0.1-100 μm, referred to as microgels, are attractive for biological applications afforded by their injectability and modularity, which allows facile delivery of mixed populations for tailored combinations of therapeutics. Significant efforts have been made to broaden methods for microgel production including via the materials and chemistries by which they are made. Via droplet-based-microfluidics we have established a method for producing click poly-(ethylene)-glycol (PEG)-based microgels with or without chemically crosslinked liposomes (lipo-microgels) through the Michael-type addition reaction between thiol and either vinyl-sulfone or maleimide groups. Unifom spherical microgels and lipo-microgels were generated with sizes of 74 ± 16 μm and 82 ± 25 μm, respectively, suggesting injectability that was further supported by rheological analyses. Super-resolution confocal microscopy was used to further verify the presence of liposomes within the lipo-microgels and determine their distribution. Atomic force microscopy (AFM) was conducted to compare the mechanical properties and network architecture of bulk hydrogels, microgels, and lipo-microgels. Further, encapsulation and release of model cargo (FITC-Dextran 5 kDa) and protein (equine myoglobin) showed sustained release for up to 3 weeks and retention of protein composition and secondary structure, indicating their ability to both protect and release cargos of interest.
Keyphrases
  • drug delivery
  • atomic force microscopy
  • hyaluronic acid
  • drug release
  • tissue engineering
  • wound healing
  • heat shock protein
  • binding protein
  • gold nanoparticles