Optimum fiber spacing in a hollow fiber bioreactor
- 5 October 1988
- journal article
- research article
- Published by Wiley in Biotechnology & Bioengineering
- Vol. 32 (8), 983-992
- https://doi.org/10.1002/bit.260320806
Abstract
A high surface area hollow fiber reactor was developed for mammalian cell culture. The reactor employs an interfiber gel matrix of agar or collagen for cell support. A model was developed to predict cell density as a function of fiber spacing. Optimum spacings are calculated for two sizes of Celgard hollow fibers. Ehrlich Ascites Tumor (EAT) cells were grown to an estimated density of 1.1 × 108 viable cells/mL in the extracapillary space—corresponding to an overall reactor density of 7 × 107 cells/mL. On the basis of available kinetic and diffusivity data, the model predicts that lactate accumulation may limit cell growth in the early stage of medium utilization, while oxygen delivery becomes limiting at later stages.Keywords
This publication has 16 references indexed in Scilit:
- Operation and pressure distribution of immobilized cell hollow fiber bioreactorsBiotechnology & Bioengineering, 1986
- A radial flow hollow fiber bioreactor for the large‐scale culture of mammalian cellsBiotechnology & Bioengineering, 1986
- Dual aerobic hollow-fiber bioreactor for cultivation ofStreptomyces aureofaciensBiotechnology & Bioengineering, 1985
- Membranes and membrane processes in biotechnologyTrends in Biotechnology, 1985
- The Large-Scale Cultivation of Mammalian CellsScientific American, 1983
- Production of anchorage-dependent cells?problems and their possible solutionsBiotechnology & Bioengineering, 1981
- Development of a hollow-fiber system for large-scale culture of mammalian cellsBiotechnology & Bioengineering, 1981
- Hormone production by cells grown in vitro on artificial capillariesExperimental Cell Research, 1974
- A theoretical model for enzymatic catalysis using asymmetric hollow fiber membranesAIChE Journal, 1974
- Cell Culture on Artificial Capillaries: An Approach to Tissue Growth in vitroScience, 1972