Biomedical Engineering Reference
In-Depth Information
[17] Card C, Hunsaker B, Smith T, Hirsch J. Near-infrared spectroscopy for rapid, simultaneous
monitoring of multiple components in mammalian cell culture. BioProcess Int 2008;6(3):
58-65.
[18] McShaneMJ, Cote GL. Near-infrared spectroscopy for determination of glucose, lactate, and
ammonia in cell culture media. Appl Spectrosc 1998;52(8):1073-1078.
[19] Wu P, Ozturk SS, Blackie JD, Thrift JC, Figueroa C, Naveh D. Evaluation and applications of
optical cell density probes in mammalian cell bioreactors. Biotechnol Bioeng 1995;45: 495-
502.
[20] Schmid G, Zacher D. Evaluation of a novel capacitance probe for on-line monitoring of
viable cell densities in batch and fed-batch animal cell culture processes. In: Animal Cell
Technology Meets Genomics, Chapter 5. Netherlands: Springer; 2005. p 621-624.
[21] Cooley RE, Stevenson CE. On-line HPLC as a process monitor in biotechnology. Process
Control Qual 1992;2:43-53.
[22] Ansorge S, Esteban G, Schmid G. On-line monitoring of infected Sf-9 insect cell cultures by
scanning permittivity measurements and comparison with off-line biovolume measurements.
Cytotechnology 2007;55:115-124.
[23] Hall JW, Rollins MJ, Macaloney G. Analyzing bioprocess systems using near-infrared
spectroscopy methods. Genet Eng News 1994;14:18.
[24] Hall JW, McNeil B, Rollins M, Draper I, Thompson BG, Macaloney G. Determination of
nutrient levels in a bioprocess. Near-infrared spectroscopic determination of acetate,
ammonium, biomass and glycerol in an industrial Escherichia coli fermentation. Appl
Spectrosc 1996;50:102-108.
[25] Brimmer PJ, Hall JW. Determination of nutrient levels in a bioprocess using near infrared
spectroscopy. Can J Spectrosc 1993;38:155-162.
[26] Larson TM, Gawlitzed M, Evans H, Albers U, Cacia J. Chemometric evaluation of on-line
high pressure liquid chromatography in mammalian cell culture: analysis of amino acids and
glucose. Biotechnol Bioeng 2002;77:553-563.
[27] Jestel NL. Process Raman spectroscopy. In: Bakeev KA, editor. Process Analytical
Technology: Spectroscopic Tools and Implementation Strategies for the Chemical and
Pharmaceutical Industries. Blackwell Publishing Ltd; 2005. p 134-169.
[28] Schustera KC, Mertensb F, Gapesa JR. FTIR spectroscopy applied to bacterial cells as a novel
method for monitoring complex biotechnological processes. Vi b Spect rosc 1999;19: 467-477.
[29] Mourant JR, Yamada YR, Carpenter S, Dominique LR, Freyer JP. FTIR spectroscopy
demonstrates biochemical differences in mammalian cell cultures at different growth stages.
Biophys J 2003;85:1938-1947.
[30] Perın V, Goicoechea M. Monitoring substrate and products in a bioprocess with FTIR
spectroscopy coupled to artificial neural networks enhanced with a genetic-algorithm-based
method for wavelength selection. Talanta 2006;68:1005-1012.
[31] Ulber R, Frerichs JG, Beutel S. Review: optical sensor systems for bioprocess monitoring.
Anal Bioanal Chem 2003;376:342-348.
[32] Fahrner RA, Blank GS. Real-time control of antibody loading during protein A affinity
chromatography using an on-line assay. J Chromatogr A 1999;849:191-196.
[33] Fahrner RA, Lester PM, Blank GS, Reifsnyder DH. Real-time control of purified product
collection during chromatography of recombinant human insulin-like growth factor-I using
an on-line assay. J Chromatogr A 1998;827:37-43.
Search WWH ::




Custom Search