Self-Organization of Long-Lasting Human Endothelial Capillary-Like Networks Guided by DLP Bioprinting.
Elsa Mazari-ArrighiMatthieu LépineDmitry AyolloLionel FaivreJérôme LargheroFrançois ChatelainAlexandra FuchsPublished in: Advanced healthcare materials (2024)
Tissue engineering holds great promise for regenerative medicine, drug discovery, and as an alternative to animal models. However, as soon as the dimensions of engineered tissue exceed the diffusion limit of oxygen and nutriments, a necrotic core forms leading to irreversible damage. To overcome this constraint, the establishment of a functional perfusion network is essential. In this work, digital light processing bioprinting is used to encapsulate endothelial progenitor cells (EPCs) in 3D light-cured hydrogel scaffolds to guide them toward vascular network formation. In these scaffolds, EPCs proliferate and self-organize within a few days into branched tubular structures with predefined geometry, forming capillary-like vascular tubes or trees of diameters in the range of 10 to 100 µm. Presenting a confluent monolayer wall of cells strongly connect by tight junctions around a central lumen-like space, these structures can be microinjected with a fluorescent dye and are stable for several weeks in vitro. These endothelial structures can be recovered and manipulated in an alginate patch without altering their shape or viability. This approach opens new opportunities for future applications, such as stacking with other cell sheets or multicellular constructs to yield bioengineered tissue with higher complexity and functionality.
Keyphrases
- tissue engineering
- endothelial cells
- drug discovery
- high resolution
- high glucose
- induced apoptosis
- oxidative stress
- single cell
- cell therapy
- magnetic resonance imaging
- cell cycle arrest
- quantum dots
- magnetic resonance
- living cells
- induced pluripotent stem cells
- contrast enhanced
- computed tomography
- case report
- bone marrow
- big data
- cell proliferation
- network analysis
- pluripotent stem cells