posted on 2016-04-25, 00:00authored byHyun-Ji Park, Yoonhee Jin, Jisoo Shin, Kisuk Yang, Changhyun Lee, Hee Seok Yang, Seung-Woo Cho
Over the last few decades, stem cell
therapies have been highlighted
for their potential to heal damaged tissue and aid in tissue reconstruction.
However, materials used to deliver and support implanted cells often
display limited efficacy, which has resulted in delaying translation
of stem cell therapies into the clinic. In our previous work, we developed
a mussel-inspired, catechol-functionalized hyaluronic acid (HA-CA)
hydrogel that enabled effective cell transplantation due to its improved
biocompatibility and strong tissue adhesiveness. The present study
was performed to further expand the utility of HA-CA hydrogels for
use in stem cell therapies to treat more clinically relevant tissue
defect models. Specifically, we utilized HA-CA hydrogels to potentiate
stem cell-mediated angiogenesis and osteogenesis in two tissue defect
models: critical limb ischemia and critical-sized calvarial bone defect.
HA-CA hydrogels were found to be less cytotoxic to human adipose-derived
stem cells (hADSCs) in vitro compared to conventional photopolymerized
HA hydrogels. HA-CA hydrogels also retained the angiogenic functionality
of hADSCs and supported osteogenic differentiation of hADSCs. Because
of their superior tissue adhesiveness, HA-CA hydrogels were able to
mediate efficient engraftment of hADSCs into the defect regions. When
compared to photopolymerized HA hydrogels, HA-CA hydrogels significantly
enhanced hADSC-mediated therapeutic angiogenesis (promoted capillary/arteriole
formation, improved vascular perfusion, attenuated ischemic muscle
degeneration/fibrosis, and reduced limb amputation) and bone reconstruction
(mineralized bone formation, enhanced osteogenic marker expression,
and collagen deposition). This study proves the feasibility of using
bioinspired HA-CA hydrogels as functional biomaterials for improved
tissue regeneration in critical tissue defects.