Abstract
We previously reported a new approach for micromanipulation and encapsulation of human stem cells using a droplet-based microfluidic device We demonstrated the possibility of encapsulating and culturing difficult-to-preserve primary human hematopoietic stem cells using an engineered double layered bead composed by an inner layer of alginate and an outer layer of puramatrix constructed using a soft technology without the use of any external force. In this work, we use this micro manipulation technique to build a 3D scaffold as a biomimetic model to recapitulate the niche of patient-derived multiple myeloma cells (MM cell) using a multilayered 3D tissue scaffold constructed in a microfluidic device and cultured in 10% FBS culture medium. In the current study, we included the use of this biomimetic model comprising supporting human Mesenchymal stem cells to show the mid-term survival of MM cells in the proposed structures. We found that the generated microniches were suitable for the maintenance of MM cells with and without supporting cells. Additionally, cultured MM cells in droplets were exposed to both Bortezomib and Lenalidomide to test their toxicity in the cultured patient derived cells. Results indicate that the maintained MM cells were consistently responding to the applied medication, opening a wide field of possibilities to use the presented micro device as an ex vivo platform for drug screening.
Highlights
Previous studies have been reported for the recapitulation of the stem cell microniche by droplet microfluidics [1]
Microfluidics have recently arisen as a promising technology for 3D cell culture as it provides the possibility of generating biomimetic structures in which native stem cell biological processes can be recapitulated [7]
The in vitro IC50 in myeloma cells (MM cell) lines varies in a range of 2–40 nM, that is the reason 8 nM and 16 nM concentrations were selected for the experiment
Summary
Previous studies have been reported for the recapitulation of the stem cell microniche by droplet microfluidics [1]. In the presented droplet-based microdevice, hydrogel droplets are produced by hydrodynamic focusing techniques and gelled by the circulation of the droplet between two laminar flows, one containing the cross-linking agent This generated droplet is coated by another synchronized hydrogel bead as previously reported, generating on demand three-dimensional niches for stem cell allocation by synchronizing droplet production rates. The presented method permits the rapid extraction of the generated cellular constructs for immediate washing and culture, limiting the time exposure of the cells to the cross-linking agent This feature allows the successful culture of cells like MM cells which usually present difficulties to be maintained ex vivo. This new technology does not require a complex setup or affective growth factor and represents a promising technique able to provide optimal requirements for 3D multiple myeloma (MM) stem cell culture for personalized medicine applications and ex vivo drug testing
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