To date, a reliable microfluidic fabrication technology for high-throughput production of SCNs for ASC culture is still lacking. Among the available technologies, droplet-based microfluidics owns the unique ability to encapsulate cells into templated matrices, although current use is limited to co-culture in droplets. There are some reports on a double encapsulation system using laminar co-flows, however, these methods do not offer control over the layer size and are not easily scalable. To date, it does not exist yet any platform for the generation of multilayer hydrogel capsules in a high throughput manner allowing a tunable construction of layers by passive forces. Therefore, the proposed technology represents an advance in its field as a novel method to generate multi-layered hydrogel beads suitable for adult stem cell encapsulation.
The expected results until the end of the project include the transfer to Europe the MicroNICHE technology developed in USA. The platform will be assessed for different cell types and concentrations. First, a HSC-niche proof-of-concept will be assessed using endothelial cells, covered by mesenchymal cells, which in turn will be covered by human hematopoietic precursor cell lines. A second proof-of-concept with primary HSCs will be also attempted.It is expected that HSCs stemless will be maintained successfully for several days on the proposed structures.
The possibility to deliver a MicroNICHE platform for improved culture of Bone Marrow Stem Cell (BMSC) products will mean an important step forward for the interest of the health of the European population. The completion and succeed of MicroNICHE as a model of stem cell niche will represent a paradigm shift in cell Technology and Regenerative Medicine, opening new ways to understanding important physiological processes. Ex vivo expansion of human HSCs in the proposed MicroNiche structure could also represent a new perspective in HPT. The developed and versatile technology which has been designed towards the recapitulation of the hematopietic stem cell niche, could also represent a novel tool to recreate other biological entities such as organs or tumours, opening insights in understanding in general 3D stem cell behavior.