Abstract
Bioengineering of tissues and organs has the potential to generate functional replacement organs. However, achieving the full-thickness vascularization that is required for long-term survival of living implants has remained a grand challenge, especially for clinically sized implants. During the pre-vascular phase, implanted engineered tissues are forced to metabolically rely on the diffusion of nutrients from adjacent host-tissue, which for larger living implants results in anoxia, cell death, and ultimately implant failure. Here it is reported that this challenge can be addressed by engineering self-oxygenating tissues, which is achieved via the incorporation of hydrophobic oxygen-generating micromaterials into engineered tissues. Self-oxygenation of tissues transforms anoxic stresses into hypoxic stimulation in a homogenous and tissue size-independent manner. The in situ elevation of oxygen tension enables the sustained production of high quantities of angiogenic factors by implanted cells, which are offered a metabolically protected pro-angiogenic microenvironment. Numerical simulations predict that self-oxygenation of living tissues will effectively orchestrate rapid full-thickness vascularization of implanted tissues, which is empirically confirmed via in vivo experimentation. Self-oxygenation of tissues thus represents a novel, effective, and widely applicable strategy to enable the vascularization living implants, which is expected to advance organ transplantation and regenerative medicine applications.
Original language | English |
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Article number | 2100850 |
Number of pages | 11 |
Journal | Advanced Functional Materials |
Volume | 31 |
Issue number | 42 |
Early online date | 6 Jul 2021 |
DOIs | |
Publication status | Published - Oct 2021 |
Keywords
- angiogenesis
- calcium peroxide
- cellular metabolism
- hydrophobic micromaterials
- implant survival
- oxygen generation
- ENDOTHELIAL-CELLS
- HYPOXIA
- VEGF
- GRADIENTS
- ANGIOGENESIS
- EXPRESSION
- SCAFFOLDS
- DELIVERY
- DEATH