Synergistic effect of Hypoxic Conditioning and Cell-Tethering Colloidal Gels enhanced Productivity of MSC Paracrine Factors and Accelerated Vessel Regeneration

Myung Chul Lee, Jae Seo Lee, Seongsoo Kim, Anurag Jamaiyar, Winona Wu, Montserrat Legorreta Gonzalez, Tania Carolina Acevedo Durán, Andrea Donaxi Madrigal-Salazar, Nicole Bassous, Violeta Carvalho, Cholong Choi, Da Seul Kim, Jeong Wook Seo, Nelson Rodrigues, Senhorinha F.C.F. Teixeira, Abdulhameed F. Alkhateeb, Javier Alejandro Lozano Soto, Mohammad Asif Hussain, Jeroen Leijten, Mark W. Feinberg*Su Ryon Shin*

*Corresponding author for this work

Research output: Contribution to journalArticleAcademicpeer-review

Abstract

Microporous hydrogels have been widely used for delivering therapeutic cells. However, several critical issues, such as the lack of control over the harsh environment they are subjected to under pathological conditions and rapid egression of cells from the hydrogels, have produced limited therapeutic outcomes. To address these critical challenges, cell-tethering and hypoxic conditioning colloidal hydrogels containing mesenchymal stem cells (MSCs) are introduced to increase the productivity of paracrine factors locally and in a long-term manner. Cell-tethering colloidal hydrogels that are composed of tyramine-conjugated gelatin prevent cells from egressing through on-cell oxidative phenolic crosslinks while providing mechanical stimulation and interconnected microporous networks to allow for host-implant interactions. Oxygenating microparticles encapsulated in tyramine-conjugated colloidal microgels continuously generated oxygen for 2 weeks with rapid diffusion, resulting in maintaining a mild hypoxic condition while MSCs consumed oxygen under severe hypoxia. Synergistically, local retention of MSCs within the mild hypoxic-conditioned and mechanically robust colloidal hydrogels significantly increased the secretion of various angiogenic cytokines and chemokines. The oxygenating colloidal hydrogels induced anti-inflammatory responses, reduced cellular apoptosis, and promoted numerous large blood vessels in vivo. Finally, mice injected with the MSC-tethered oxygenating colloidal hydrogels significantly improved blood flow restoration and muscle regeneration in a hindlimb ischemia (HLI) model.

Original languageEnglish
Article number2408488
JournalAdvanced materials
DOIs
Publication statusE-pub ahead of print/First online - 9 Oct 2024

Keywords

  • 2024 OA procedure
  • hMSC
  • hypoxic conditioning
  • ischemic disease
  • mechanical stimulation
  • oxygenating microparticles
  • paracrine effect
  • vessel regeneration
  • colloidal gel

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