Publication

[20] "Observations Consistent with Autocrine Stimulation of Hybridoma Cell Growth and Implication for Large-scale Antibody Production", G. M. Lee, M. S. Kaminski, and B. O. Palsson, Biotechnol. Lett., 14:257-262 (1992). 

[19] "Production of Monoclonal Antibody Using Free and Immobilized Hybridoma Cells: Effect of Serum", G. M. Lee, A. Varma and B. O. Palsson, Biotechnol. Bioeng., 38:821-830 (1991). 

[18] "Effect of Trisodium Citrate Treatment on Hybridoma Cell Viability", G. M. Lee, J. Gray, and B. O. Palsson, Biotechnol. Techniques, 4:295-298 (1991). 

[17] "Application of Population Balance Model to the Loss of Hybridoma Antibody Productivity", G. M. Lee, A. Varma and B. O. Palsson, Biotechnol. Prog., 7:72-75 (1991). 

[16] "Immobilization Can Improve the Stability of Hybridoma Antibody Productivity in Serum-free Media", G. M. Lee and B. O. Palsson, Biotechnol. Bioeng., 36:1049-1055 (1990). 

[15] "Simplified Method of Making Alginate-polylysine Microcapsules for Hybridoma Cell Culture Using RPMI 1640 Medium", G. M. Lee and B. O. Palsson, Biotechnol. Techniques, 4:341-344 (1990). 

[14] "Serum Can Act as a Shear Protecting Agent in Agitated Hybridoma Cell Cultures", G. M. Lee, J. M. Savinell and B. O. Palsson, Hybridoma, 8:639-645 (1989). 

[13] "Effect of Serum Concentration on Hybridoma Cell Growth and Monoclonal Antibody Production at Various Initial Cell Densities", G. M. Lee, T. K. Huard and B. O. Palsson, Hybridoma, 8:369-375 (1989). 

[12] "On the Orders of Magnitude of Epigenic Dynamics and the Rate of Monoclonal Antibody Production", J. M. Savinell, G. M. Lee and B. O. Palsson, Bioprocess Engr., 4:231-234 (1989). 

[11] "Effect of Mechanical Agitation on Hybridoma Cell Growth Rate". G. M. Lee, T. K. Huard, M. S. Kaminski and B. O. Palsson, Biotechnol. Lett., 10:625-628 (1988). 

[10] "Effect of Anchorage Dependency on Growth Rate and Monoclonal Antibody Production of Hybridoma Cells", G. M. Lee, T. K. Huard and B. O. Palsson, Biotechnol. Lett., 10:307-312 (1988). 

[9] "Immobilization of Zymomonas mobilis and Amyloglucosidase for Ethanol production from Sago Starch", C. H. Kim, G. M. Lee, Z. Abidin, M. H. Han and S. K. Rhee, Enzyme Microb. Technol., 10:426-430 (1988). 

[8] "Continuous Ethanol Production from Sago Starch Using Immobilized Amyloglucosidase and Zymomonas Mobilis", G. M. Lee, C. H. Kim, Z. Abidin, M. H. Han and S. K. Rhee, J. Ferment. Technol., 65:531-535 (1987). 

[7] "Sago Starch Saccharification and Simultaneous Ethanol Fermentation by Amyloglucosidase and Zymomonas mobilis", G. M. Lee, C. H. Kim, Z. Abidin, M. H. Han and S. K. Rhee, J. Chem. Technol. Biotechnol., 38:235-242 (1987). 

[6] "Plasmid Maintenance and Growth of Recombinant Saccharomyces cerevisiae Producing Hepatitis B Virus Surface Antigen", G. M. Lee, K. B. Song, S. K. Rhee and M. H. Han, Biotechnol. Lett., 8:385-390 (1986). 

[5] "Simultaneous Sago Starch Hydrolysis and Ethanol Production by Zymomonas mobilis and Glucoamylase", S. K. Rhee, G. M. Lee, C. H. Kim, Z. Abidin and M. H. Han, Biotechnol. Bioeng. Symp., 17:481-493 (1986). 

[4] "Simultaneous Saccharification of Ethanol Fermentation of Sago Starch Using Immobilized Zymomonas mobilis", G. M. Lee, C. H. Kim, K. J. Lee, Z. Abidin, M. H. Han and S. K. Rhee, J. Ferment. Technol., 64:293297 (1986). 

[3] "Biotransformation of Rifamycin B to Rifamycin S Using Immobilized Whole Cell of Humicola spp. in a Fluidized Bed Reactor", G. M. Lee, C. Y. Choi, J. M. Park and M. H. Han, J. Chem. Tech. Biotechnol., 35B:3-10 (1985). 

[2] "Ethanol Production from Cassava and Sago Starch Using Zymomonas mobilis", S. K. Rhee, G. M. Lee, Y. T. Han, Z. Abidin, M. H. Han and K. J. Lee, Biotechnol. Lett., 6:615-620 (1984). 

[1] "The Properties of Immobilized Whole Cell of Humicola spp. with Rifamycin Oxidase Activity", G. M. Lee, C. Y. Choi, J. M. Park and M. H. Han, Biotechnol. Lett., 6:143-148 (1984). 

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