Microinterfaces in biopolymer-based bicontinuous hydrogels guide rapid 3D cell migration.
Karen L XuNikolas Di CaprioHooman FallahiMohammad DehghanyMatthew D DavidsonLorielle LaforestBrian C H CheungYuqi ZhangMingming WuVivek B ShenoyLin HanRobert Leon MauckJason A BurdickPublished in: Nature communications (2024)
Cell migration is critical for tissue development and regeneration but requires extracellular environments that are conducive to motion. Cells may actively generate migratory routes in vivo by degrading or remodeling their environments or instead utilize existing extracellular matrix microstructures or microtracks as innate pathways for migration. While hydrogels in general are valuable tools for probing the extracellular regulators of 3-dimensional migration, few recapitulate these natural migration paths. Here, we develop a biopolymer-based bicontinuous hydrogel system that comprises a covalent hydrogel of enzymatically crosslinked gelatin and a physical hydrogel of guest and host moieties bonded to hyaluronic acid. Bicontinuous hydrogels form through controlled solution immiscibility, and their continuous subdomains and high micro-interfacial surface area enable rapid 3D migration, particularly when compared to homogeneous hydrogels. Migratory behavior is mesenchymal in nature and regulated by biochemical and biophysical signals from the hydrogel, which is shown across various cell types and physiologically relevant contexts (e.g., cell spheroids, ex vivo tissues, in vivo tissues). Our findings introduce a design that leverages important local interfaces to guide rapid cell migration.
Keyphrases
- hyaluronic acid
- cell migration
- extracellular matrix
- stem cells
- single cell
- cell therapy
- gene expression
- immune response
- loop mediated isothermal amplification
- induced apoptosis
- drug delivery
- molecular dynamics simulations
- bone marrow
- physical activity
- mental health
- wound healing
- high resolution
- cell proliferation
- single molecule
- ionic liquid
- sensitive detection
- high speed
- water soluble