Hydrogel oxygen reservoirs increase functional integration of neural stem cell grafts by meeting metabolic demands

• Published in: Nature communications Vol. 14; no. 1; pp. 457 - 11
• Main Authors: Wang, Y., Zoneff, E. R., Thomas, J. W., Hong, N., Tan, L. L., McGillivray, D. J., Perriman, A. W., Law, K. C. L., Thompson, L. H., Moriarty, N., Parish, C. L., Williams, R. J., Jackson, C. J., Nisbet, D. R.
• Format: Journal Article
• Language: English
• Published: London Nature Publishing Group UK 28.01.2023; Nature Publishing Group; Nature Portfolio
• Subjects: 13; 13/1; 13/106; 14/19; 14/28; 631/378/1934; 631/61/2296; 631/61/54/1754; 639/166/985; 639/301/54/2295; 82/51; 82/83; Biomimetics; Brain injury; Cell Differentiation; Cell fate; Cell survival; Differentiation; Engraftment; Functional integration; Grafting; Humanities and Social Sciences; Hydrogels; Hydrogels - metabolism; Hypoxia; Innervation; Integration; multidisciplinary; Myoglobin - metabolism; Myoglobins; Neural cell transplants; Neural networks; Neural stem cells; Neural Stem Cells - metabolism; Neurons - metabolism; Oxygen; Oxygen - metabolism; Peptides; Progenitor cells; Regenerative medicine; Science; Science (multidisciplinary); Stem cells; Survival; Tissue engineering; Transplantation; Vectors
• ISSN: 2041-1723; 2041-1723
• DOI: 10.1038/s41467-023-36133-8

Injectable biomimetic hydrogels have great potential for use in regenerative medicine as cellular delivery vectors. However, they can suffer from issues relating to hypoxia, including poor cell survival, differentiation, and functional integration owing to the lack of an established vascular network. Here we engineer a hybrid myoglobin:peptide hydrogel that can concomitantly deliver stem cells and oxygen to the brain to support engraftment until vascularisation can occur naturally. We show that this hybrid hydrogel can modulate cell fate specification within progenitor cell grafts, resulting in a significant increase in neuronal differentiation. We find that the addition of myoglobin to the hydrogel results in more extensive innervation within the host tissue from the grafted cells, which is essential for neuronal replacement strategies to ensure functional synaptic connectivity. This approach could result in greater functional integration of stem cell-derived grafts for the treatment of neural injuries and diseases affecting the central and peripheral nervous systems. Injectable biomimetic hydrogels hold significant promise for tissue engineering applications. Here, the authors present a hybrid myoglobin:peptide hydrogel to overcome a critical oxygen shortage following neural stem cell transplantation, thus increasing cell survival and integration.