Conductive gradient hydrogels allow spatial control of adult stem cell fate.
Shang SongKelly W McConnellDingying ShanCheng ChenByeongtaek OhJindi SunAda S Y PoonPaul M GeorgePublished in: Journal of materials chemistry. B (2024)
Electrical gradients are fundamental to physiological processes including cell migration, tissue formation, organ development, and response to injury and regeneration. Current electrical modulation of cells is primarily studied under a uniform electrical field. Here we demonstrate the fabrication of conductive gradient hydrogels (CGGs) that display mechanical properties and varying local electrical gradients mimicking physiological conditions. The electrically-stimulated CGGs enhanced human mesenchymal stem cell (hMSC) viability and attachment. Cells on CGGs under electrical stimulation showed a high expression of neural progenitor markers such as Nestin, GFAP, and Sox2. More importantly, CGGs showed cell differentiation toward oligodendrocyte lineage (Oligo2) in the center of the scaffold where the electric field was uniform with a greater intensity, while cells preferred neuronal lineage (NeuN) on the edge of the scaffold on a varying electric field at lower magnitude. Our data suggest that CGGs can serve as a useful platform to study the effects of electrical gradients on stem cells and potentially provide insights on developing new neural engineering applications.
Keyphrases
- stem cells
- induced apoptosis
- cell fate
- tissue engineering
- cell cycle arrest
- cell migration
- mesenchymal stem cells
- drug delivery
- endoplasmic reticulum stress
- poor prognosis
- signaling pathway
- cell death
- single cell
- hyaluronic acid
- cell proliferation
- long non coding rna
- young adults
- gold nanoparticles
- pi k akt
- drug release
- extracellular matrix
- umbilical cord
- blood brain barrier
- big data
- pluripotent stem cells