Interwoven Four-Compartment Capillary Membrane Technology for Three-Dimensional Perfusion with Decentralized Mass Exchange to Scale Up Embryonic Stem Cell Culture

Interwoven Four-Compartment Capillary Membrane Technology for Three-Dimensional Perfusion with Decentralized Mass Exchange to Scale Up Embryonic Stem Cell Culture

We describe hollow fiber-based three-dimensional (3D) dynamic perfusion bioreactor technology for embryonic stem cells (ESC) which is scalable for laboratory and potentially clinical translation applications. We added 2 more compartments to the typical 2-compartment devices, namely an additional med...

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Veröffentlicht in:Cells, tissues, organs tissues, organs, 2010-01, Vol.192 (1), p.39-49
Hauptverfasser: Gerlach, Jörg C., Lübberstedt, Marc, Edsbagge, Josefina, Ring, Alexander, Hout, Mariah, Baun, Matt, Rossberg, Ingrid, Knöspel, Fanny, Peters, Grant, Eckert, Klaus, Wulf-Goldenberg, Annika, Björquist, Petter, Stachelscheid, Harald, Urbaniak, Thomas, Schatten, Gerald, Miki, Toshio, Schmelzer, Eva, Zeilinger, Katrin
Format: Artikel
Sprache:eng
Schlagworte:
Animals
Bioreactors
Cell Culture Techniques - instrumentation
Cell Culture Techniques - methods
Cell Growth Processes - physiology
Cells, Cultured
Embryonic Stem Cells - cytology
Humans
Mice
Original Paper
Perfusion
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Zusammenfassung:We describe hollow fiber-based three-dimensional (3D) dynamic perfusion bioreactor technology for embryonic stem cells (ESC) which is scalable for laboratory and potentially clinical translation applications. We added 2 more compartments to the typical 2-compartment devices, namely an additional media capillary compartment for countercurrent ‘arteriovenous’ flow and an oxygenation capillary compartment. Each capillary membrane compartment can be perfused independently. Interweaving the 3 capillary systems to form repetitive units allows bioreactor scalability by multiplying the capillary units and provides decentralized media perfusion while enhancing mass exchange and reducing gradient distances from decimeters to more physiologic lengths of
ISSN:1422-6405
1422-6421
DOI:10.1159/000291014