Cell-Instructive Microgels with Tailor-Made Physicochemical Properties.

A microfluidic in vitro cell encapsulation platform to systematically test the effects of microenvironmental parameters on cell fate in 3D is developed. Multiple cell types including fibroblasts, embryonic stem cells, and cancer cells are incorporated in enzymatically cross-linked poly(ethylene glycol)-based microgels having defined and tunable mechanical and biochemical properties. Furthermore, different approaches to prevent cell "escape" from the microcapsules are explored and shown to substantially enhance the potential of this technology. Finally, coencapsulation of microgels within nondegradable gels allows cell viability, proliferation, and morphology to be studied in different microenvironmental conditions up to two weeks in culture.

Microcarrier suspension cultures for high-density expansion and differentiation of human pluripotent stem cells to neural progenitor cells.

Neural progenitor cells (NPCs) derived from human induced pluripotent stem cells (hiPSCs) can be differentiated to neural cells that model neurodegenerative diseases and be used in the screening of potential drugs to ameliorate the disease phenotype. Traditionally, NPCs are produced in 2D cultures, in low yields, using a laborious process that includes generation of embryonic bodies, plating, and colony selections. To simplify the process and generate large numbers of hiPSC-derived NPCs, we introduce a microcarrier (MC) system for the expansion of a hiPSC line and its subsequent differentiation to NPC, using iPS (IMR90) as a model cell line. In the expansion stage, a process of cell propagation in serum-free MC culture was developed first in static culture, which is then scaled up in stirred spinner flasks. A 7.7-fold expansion of iPS (IMR90) and cell yield of 1.3×106 cells/mL in 7 days of static MC culture were achieved. These cells maintained expression of OCT 3/4 and TRA-1-60 and possessed a normal karyotype over 10 passages. A higher cell yield of 6.1×106 cells/mL and 20-fold hiPSC expansion were attained using stirred spinner flasks (seeded from MC static cultures) and changing the medium-exchange regimen from once to twice a day. In the differentiation stage, NPCs were generated with 78%-85% efficiency from hiPSCs using a simple serum-free differentiation protocol. Finally, the integrated process of cell expansion and differentiation of hiPSCs into NPCs using an MC in spinner flasks yielded 333 NPCs per seeded hiPSC as compared to 53 in the classical 2D tissue culture protocol. Similar results were obtained with the HES-3 human embryonic stem cell line. These NPCs were further differentiated into ßIII-tubulin⁺ neurons, GFAP⁺ astrocytes, and O4⁺ oligodendrocytes, showing that cells maintained their multilineage differentiation potential.

Impact of vitronectin concentration and surface properties on the stable propagation of human embryonic stem cells.

The standard method for culturing human embryonic stem cells (hESC) uses supporting feeder layers of cells or an undefined substrate, Matrigel(™), which is a basement membrane extracted from murine sarcoma. For stem cell therapeutic applications, a superior alternative would be a defined, artificial surface that is based on immobilized human plasma vitronectin (VN), which is an adhesion-mediating protein. Therefore, VN adsorbed to diverse polymer surfaces was explored for the continuous propagation of hESC. Cells propagated on VN-coated tissue culture polystyrene (TCPS) are karyotypically normal after >10 passages of continuous culture, and are able to differentiate into embryoid bodies containing all three germ layers. Expansion rates and pluripotent marker expression verified that a minimal VN surface density threshold is required on TCPS. Further exploration of adsorbed VN was conducted on polymer substrates with different properties, ranging from hydrophilic to hydrophobic and including cationic and anionic polyelectrolyte coatings. Despite differing surface properties, these substrates adsorbed VN above the required surface density threshold and were capable of supporting hESC expansion for >10 passages. Correlating wettability of the VN-coated surfaces with the response of cultured hESC, higher cell expansion rates and OCT-4 expression levels were found for VN-coated TCPS, which exhibits a water contact angle close to 65°. Importantly, this simple, defined surface matches the performance of the benchmark Matrigel, which is a hydrogel with highly complex composition.