Summary

Encapsulation alginate de cellules souches pluripotentes en utilisant une buse de co-axiale

Published: July 02, 2015
doi:

Summary

We established a method of encapsulating pluripotent stem cells (PS cells) into alginate hydrogel capsules using a co-axial nozzle. This prevents cells from aggregating excessively and limits the shear stress experienced by cells in suspension culture. The technique is applicable to the mass production of PS cells as well as research on stem cell niche.

Abstract

Pluripotent stem cells (PS cells) are the focus of intense research due to their role in regenerative medicine and drug screening. However, the development of a mass culture system would be required for using PS cells in these applications. Suspension culture is one promising culture method for the mass production of PS cells, although some issues such as controlling aggregation and limiting shear stress from the culture medium are still unsolved. In order to solve these problems, we developed a method of calcium alginate (Alg-Ca) encapsulation using a co-axial nozzle. This method can control the size of the capsules easily by co-flowing N2 gas. The controllable capsule diameter must be larger than 500 µm because too high a flow rate of N2 gas causes the breakdown of droplets and thus heterogeneous-sized capsules. Moreover, a low concentration of Alg-Na and CaCl2 causes non-spherical capsules. Although an Alg-Ca capsule without a coating of Alg-PLL easily dissolves enabling the collection of cells, they can also potentially leak out from capsules lacking an Alg-PLL coating. Indeed, an alginate-PLL coating can prevent cellular leakage but is also hard to break. This technology can be used to research the stem cell niche as well as the mass production of PS cells because encapsulation can modify the micro-environment surrounding cells including the extracellular matrix and the concentration of secreted factors.

Introduction

Induced pluripotent stem cells (iPS cells) are currently the source of intense research due to their role in regenerative medicine. However, huge amounts of cells are required for tissue regeneration. For instance approximately one billion pancreatic cells required for a type 1 diabetic patient1. However, conventional dish culture is only able to obtain 1 × 105 cells/cm2, thus requiring 1 m2 of culture area to obtain enough stem cell-derived pancreatic cells to treat a type 1 diabetic patient. The development of a system for the mass-culture of pluripotent stem cells, such as microcarrier2 and suspension culture is therefore required for regenerative medicine. Suspension culture represents a promising method of mass culture but controlling the aggregation of cells is challenging in direct suspension cultures of human iPS cells3. Indeed, suspended cells are exposed to shear stress, which causes cell damage3 or differentiation4.

Research into hydrogel-based encapsulation has been conducted to solve problems associated with suspension culture. In hydrogel capsules, cells are protected from the flow of the medium. Previous reports have documented the use of various types of hydrogel, including agarose5, PEG6, and alginate (Alg), for cellular encapsulation. Alg-Ca hydrogel is one of the most useful hydrogels for cell encapsulation because Alg−Ca hydrogel is formed immediately after dropping alginate solution into a CaCl2 solution and is also readily digested by enzymes or chelating reagents.

Here, we have established a stable alginate encapsulation process for iPS cells using a co-axial nozzle. By using N2 gas flow for forming droplets, it is possible to encapsulate cells into uniform capsules without the need for other reagents such as oil. In this method, the flow rate of N2 and concentration of both CaCl2 and alginate are the major operating conditions affecting the size, shape, and uniformity of capsules. This report demonstrates the optimization of these operating conditions through the use of a hi-speed camera and a microscope.

Protocol

1. Matériaux Préparation Préparer tampon HEPES 10 mM. Ajuster le pH à 7,0 à température ambiante et ajouter du NaCl à 0,9%. Préparer la solution d'alginate à 5% et une solution 10 mM d'EDTA en mélangeant une solution saline tamponnée au HEPES préparé en 1.1. Ajuster le pH à 7,0 à température ambiante. Autoclave les réactifs (1.1, 1.2) pendant 20 min à 121 ° C. Préparer des plats 60 mm revêtues de gélatine en couches avec de 1,2 à 2,0 × 10 6</s…

Representative Results

Au protocole 2.5, la solution d'alginate expulsé forme une forme sphérique immédiatement après l'expulsion (Figure 2A – H). Si la suspension est expulsé avec une vitesse d'écoulement inférieure à 2 N 1L / min, la taille des gouttelettes est uniforme (figure 2I). Cependant, si le débit de N 2 est supérieur à 1 L / min, la gouttelette tombe en panne (figure 2G, repéré par une flèche blanche) et la taille des gouttelettes dev…

Discussion

culture d'encapsulation peut être comparé à des cultures en suspension directe. Suspension de culture est un procédé plus simple d'obtenir de grandes quantités de cellules souches pluripotentes que les méthodes d'encapsulation. Toutefois, le contrôle de l'agrégation des cellules en culture en suspension est encore difficile. Dans le procédé d'encapsulation, l'agrégation cellulaire est limitée dans des capsules et peuvent donc être bien contrôlée. Une publication antérieure …

Divulgaciones

The authors have nothing to disclose.

Acknowledgements

This research was supported by the S-Innovation project of the Japan Science and technology Agency (JST), the Graduate Program for Leaders in Life Innovation (GPLLI) of the University of Tokyo, and the Research Fellowship for Young Scientists of Japan Society for the Promotion of Science. We thank nac Image Technology Inc. for taking movies using a hi-speed camera.

Materials

Mouse embryo fibroblast Cell Biolabs SNL 76/7
Mouse induced pluripotent stem cell RIKEN Bio resorce centre iPS-MEF-Ng-20D-17
DMEM high-glucose GIBCO 11995
ES qualified  FBS GIBCO 16141079
Antibacterial Antibiotics GIBCO 15240
Nonessential Amino Acid GIBCO 11140
2-mercaptoethanol GIBCO 21985-023
ESGRO Leukemia Inhibitory Factor Merck Millipore ESG1107
Trypsin/EDTA GIBCO 25300
26G/16G needle Hoshiseido
10 mL Syringe TERUMO SS-10ESZ
Sodium  Chloride Wako 191-01665
HEPES SIGMA H4034
Sodium Alginate Wako 194-09955
Calcium Chloride Wako 039-00475
Poly-L-lysine (Mw=15,000-30,000) SIGMA P7890
EDTA DOJINDO 345-01865
Sylinge pump AS ONE
Microscope Olympus IX71
Microscope Leica DM IRB
Hispeed camera nac image technology Memrecam HX-3

Referencias

  1. Zweigerdt, R. Large scale production of stem cells and their derivatives. Adv. Biochem. Eng. Biotechnol. 114, 201-235 (2009).
  2. Chen, A., Chen, X., Choo, A. B. H., Reuveny, S., Oh, S. K. W. Critical microcarrier properties affecting the expansion of undifferentiated human embryonic stem cells. Stem cell Res. 7 (2), 97-111 (2011).
  3. Schroeder, M., et al. Differentiation and lineage selection of mouse embryonic stem cells in a stirred bench scale bioreactor with automated process control. Biotechnol. Bioeng. 92 (7), 920-933 (2005).
  4. Leung, H. W., Chen, A., Choo, A. B. H., Reuveny, S., Oh, S. K. W. Agitation can induce differentiation of human pluripotent stem cells in microcarrier cultures. Tissue Eng. Part C. 17 (2), 165-172 (2011).
  5. Dang, S. M., Gerecht-Nir, S., Chen, J., Itskovitz-Eldor, J., Zandstra, P. W. Controlled, scalable embryonic stem cell differentiation culture. Stem Cells. 22 (3), 275-282 (2004).
  6. Weber, L. M., He, J., Haskins, K., Anseth, K. S. PEG-based hydrogels as an in vitro encapsulation platform for testing controlled for testing controlled ß-cell microenvironments. Acta Biomater. 2 (1), 1-8 (2006).
  7. Horiguchi, I., Chowdhury, M. M., Sakai, Y., Tabata, Y. Proliferation, morphology, and pluripotency of mouse induced pluripotent stem cells in three different types of alginate beads for mass production. Biotechnol. Prog. 30 (4), 896-904 (2014).
  8. Rahman, N., Purpura, K. A., Wylie, R. G., Zandstra, P. W., Shoichet, M. S. The use of vascular endothelial growth factor functionalized agarose to guide pluripotent stem cell aggregates toward blood progenitor cells. Biomaterials. 31 (32), 8262-8270 (2010).
  9. Siti-Ismail, N., Bishop, A. E., Polak, J. M., Mantalaris, A. The benefit of human embryonic stem cell encapsulation for prolonged feeder-free maintenance. Biomaterials. 29, 3946-3952 (2008).
  10. Magyer, J. P., Nemir, M., Ehler, E., Suter, N., Perriard, J., Eppenberger, H. M. Mass Production of Embryoid Bodies in Microbeads. Ann. N. Y. Acad. Sci. 944, 135-143 (2001).
  11. Xu, J., Li, S., Tan, J., Luo, G. Controllable Preparation of Monodispersed Calcium Alginate Microbeads in a Novel Microfluidic System. Chem. Eng. Technol. 31 (8), 1223-1226 (2008).
  12. Sakai, M. P., Y, Development of Bioactive Hydrogel Capsules for The 3D Expansion of Pluripotent Stem Cells in Bioreactors. Biomater. Sci. 2 (176), 176-183 (2014).
  13. Chowdhury, M. M., Katsuda, T., Montagne, K., Kimura, H., Kojima, N., Akutsu, H., Ochiya, T., Fujii, T., Sakai, Y. Enhanced effects of secreted soluble factor preserve better pluripotent state of embry- onic stem cell culture in a membrane-based compartmentalized micro-bioreactor. Biomed. Microdevices. 12 (6), 1097-1105 (2010).
  14. Chowdhury, M. M., Kimura, H., Fujii, T., Sakai, Y. Induction of alternative fate other than default neuronal fate of embryonic stem cells in a membrane-based two-chambered micro- bioreactor by cell-secreted BMP4. Biomicrofluidics. 6 (1), 14117-14117-13 (2012).

Play Video

Citar este artículo
Horiguchi, I., Sakai, Y. Alginate Encapsulation of Pluripotent Stem Cells Using a Co-axial Nozzle. J. Vis. Exp. (101), e52835, doi:10.3791/52835 (2015).

View Video