TY - BOOK TI - Higher order chromatin structure of the ovomucoid-ovoinhibitor gene complex AU - Scott, Maxwell John DA - 1986/// PY - 1986/// PB - Baylor College of Medicine ER - TY - JOUR TI - Hollow Fiber Microfiltration Methods for Recovery of Rat Basophilic Leukemia Cells (RBL-2H3) From Tissue Culture Media AU - Shiloach, Joseph AU - Kaufman, Jeanne B. AU - Kelly, Robert M. T2 - Biotechnology Progress AB - Biotechnology ProgressVolume 2, Issue 4 p. 230-233 Article Hollow Fiber Microfiltration Methods for Recovery of Rat Basophilic Leukemia Cells (RBL—2H3) From Tissue Culture Media Joseph Shiloach, Joseph Shiloach Biotechnology Unit, NIDDK, National Institutes of Health, Bethesda, Maryland 20892 Joseph Shiloach: is the head of the Biotechnology (Pilot Plant) Unit at the National Institutes of Health in Bethesda, Maryland. He received his Ph.D. from the Hebrew University in Jerusalem, Israel. He is heavily involved in fermentation processes, mammalian cell growth and recovery process of compounds with biological activity.Search for more papers by this authorJeanne B. Kaufman, Jeanne B. Kaufman Biotechnology Unit, NIDDK, National Institutes of Health, Bethesda, Maryland 20892 Jeanne Kaufman: received her B.S. in Biology at St. Mary's College in Maryland. She is currently with the Biotechnology unit at the National Institutes of Health. She is responsible for the growth of the mammalian cell culture on small and large scale.Search for more papers by this authorRobert M. Kelly, Robert M. Kelly Department of Chemical Engineering, The Johns Hopkins University, Baltimore, Maryland 21218 Robert M. Kelly: is currently assistant professor of chemical engineering at the Johns Hopkins University in Baltimore, Maryland where he has been since 1981. He received his Ph.D. in chemical engineering from North Carolina State University. His research interests include separation processes, especially chemical absorption and stripping, and biochemical engineering with emphasis on engineering problems related to the growth and utilization of bacteria from extreme environments.Search for more papers by this author Joseph Shiloach, Joseph Shiloach Biotechnology Unit, NIDDK, National Institutes of Health, Bethesda, Maryland 20892 Joseph Shiloach: is the head of the Biotechnology (Pilot Plant) Unit at the National Institutes of Health in Bethesda, Maryland. He received his Ph.D. from the Hebrew University in Jerusalem, Israel. He is heavily involved in fermentation processes, mammalian cell growth and recovery process of compounds with biological activity.Search for more papers by this authorJeanne B. Kaufman, Jeanne B. Kaufman Biotechnology Unit, NIDDK, National Institutes of Health, Bethesda, Maryland 20892 Jeanne Kaufman: received her B.S. in Biology at St. Mary's College in Maryland. She is currently with the Biotechnology unit at the National Institutes of Health. She is responsible for the growth of the mammalian cell culture on small and large scale.Search for more papers by this authorRobert M. Kelly, Robert M. Kelly Department of Chemical Engineering, The Johns Hopkins University, Baltimore, Maryland 21218 Robert M. Kelly: is currently assistant professor of chemical engineering at the Johns Hopkins University in Baltimore, Maryland where he has been since 1981. He received his Ph.D. in chemical engineering from North Carolina State University. His research interests include separation processes, especially chemical absorption and stripping, and biochemical engineering with emphasis on engineering problems related to the growth and utilization of bacteria from extreme environments.Search for more papers by this author First published: December 1986 https://doi.org/10.1002/btpr.5420020411Citations: 9 AboutPDF ToolsRequest permissionExport citationAdd to favoritesTrack citation ShareShare Give accessShare full text accessShare full-text accessPlease review our Terms and Conditions of Use and check box below to share full-text version of article.I have read and accept the Wiley Online Library Terms and Conditions of UseShareable LinkUse the link below to share a full-text version of this article with your friends and colleagues. Learn more.Copy URL Citing Literature Volume2, Issue4December 1986Pages 230-233 RelatedInformation DA - 1986/12// PY - 1986/12// DO - 10.1002/btpr.5420020411 VL - 2 IS - 4 SP - 230-233 J2 - Biotechnol Progress LA - en OP - SN - 8756-7938 1520-6033 UR - http://dx.doi.org/10.1002/btpr.5420020411 DB - Crossref ER - TY - JOUR TI - Experimental methods for measuring static liquid holdup in packed columns AU - Schubert, C. N. AU - Lindner, J. R. AU - Kelly, R. M. T2 - AIChE Journal AB - AIChE JournalVolume 32, Issue 11 p. 1920-1923 R & D Note Experimental methods for measuring static liquid holdup in packed columns C. N. Schubert, C. N. Schubert Department of Chemical Engineering, Johns Hopkins University, Baltimore, MD 21218Search for more papers by this authorJ. R. Lindner, J. R. Lindner Department of Chemical Engineering, Johns Hopkins University, Baltimore, MD 21218Search for more papers by this authorR. M. Kelly, Corresponding Author R. M. Kelly Department of Chemical Engineering, Johns Hopkins University, Baltimore, MD 21218Department of Chemical Engineering, Johns Hopkins University, Baltimore, MD 21218Search for more papers by this author C. N. Schubert, C. N. Schubert Department of Chemical Engineering, Johns Hopkins University, Baltimore, MD 21218Search for more papers by this authorJ. R. Lindner, J. R. Lindner Department of Chemical Engineering, Johns Hopkins University, Baltimore, MD 21218Search for more papers by this authorR. M. Kelly, Corresponding Author R. M. Kelly Department of Chemical Engineering, Johns Hopkins University, Baltimore, MD 21218Department of Chemical Engineering, Johns Hopkins University, Baltimore, MD 21218Search for more papers by this author First published: November 1986 https://doi.org/10.1002/aic.690321119Citations: 29AboutPDF ToolsRequest permissionExport citationAdd to favoritesTrack citation ShareShare Give accessShare full text accessShare full-text accessPlease review our Terms and Conditions of Use and check box below to share full-text version of article.I have read and accept the Wiley Online Library Terms and Conditions of UseShareable LinkUse the link below to share a full-text version of this article with your friends and colleagues. Learn more.Copy URL Literature cited Baldi, G., and S., Sicardi, “A Model for Mass Transfer with and without Chemical Reaction in Packed Towers,” Chem. Eng. Sci., 30, 617 (1975). Bennett, A., and F., Goodridge, “Hydrodynamic and Mass Transfer Studies in Packed Absorption Columns,” Trans. Inst. Chem. Engrs., 48, T232 (1970). Hoogendoorn, C. J., and J., Lips, “Axial Mixing of Liquid in Gas-Liquid Flow through Packed Beds,” Can. J. Chem. Eng., 43, 125 (1965). Joosten, G. E. H., and P. V., Dankwerts, “Chemical Reaction and Effective Interfacial Areas in Gas Absorption,” Chem. Eng. Sci., 28, 453 (1973). Patwardhan, V. S., “Effective Interfacial Area in Packed Beds for Absorption with Chemical Reaction,” Can. J. Chem. Eng., 56, 56 (1978). Patwardhan, V. S., and V. R., Shrotri, “Mass Transfer Coefficient between the Static and Dynamic Holdups in a Packed Column,” Chem. Eng. Commun., 10, 349 (1981). Puranik, S. S., and A., Vogelpohl, “Effective Interfacial Area in Irrigated Packed Columns,” Chem. Eng. Sci., 29, 501 (1974). Ruszkay, R. D., “ Transient Response of Liquid Flowing through Packed Tower with Air Counterflow,” Ph.D. Thesis, Columbia Univ. (1963). Shulman, H. L., C. F., Ullrich, and N. Wells, “Performance of Packed Columns. 1: Total, Static, and Operating Holdups,” AIChE J., 1, 247 (1955). van Swaaij, W. P. M., J. C. Charpentier, and J. Villermaux, “Residence Time Distribution in the Liquid Phase of Trickle Flow in Packed Columns,” Chem. Eng. Sci., 24, 1,083 (1969). Citing Literature Volume32, Issue11November 1986Pages 1920-1923 ReferencesRelatedInformation DA - 1986/11// PY - 1986/11// DO - 10.1002/aic.690321119 VL - 32 IS - 11 SP - 1920-1923 J2 - AIChE J. LA - en OP - SN - 0001-1541 1547-5905 UR - http://dx.doi.org/10.1002/aic.690321119 DB - Crossref ER - TY - JOUR TI - Microbiological Metal Transformations: Biotechnological Applications and Potential AU - Olson, Gregory J. AU - Kelly, Robert M. T2 - Biotechnology Progress AB - Biotechnology ProgressVolume 2, Issue 1 p. 1-15 Biotechnology Progress Topics Microbiological Metal Transformations: Biotechnological Applications and Potential Gregory J. Olson, Gregory J. Olson Surface Chemistry and Bioprocesses Group, National Bureau of Standards, Gaithersburg, MD 20899 Gregory J. Olson: is currently a research microbiologist in the Institute for Materials Science and Engineering at the National Bureau of Standards in Gaithersburg, Maryland. He received a Ph.D. in Microbiology from Montana State University in 1978 and joined NBS as a National Research Council Postdoctoral Fellow (1979–81). His current research interests include biological transformations of materials and development and application of molecular measurement methods to characterize these processes.Search for more papers by this authorRobert M. Kelly, Robert M. Kelly Department of Chemical Engineering, The Johns Hopkins University, Baltimore, MD 21218 Robert M. Kelly: is currently assistant professor of chemical engineering at the Johns Hopkins University in Baltimore, Maryland where he has been since 1981. He received his BS and MS from the University of Virginia and a Ph.D. in chemical engineering from North Carolina State University. Prior to his doctoral work, he was employed with the du Pont Company at Marshall Laboratory in Philadelphia. His research interests include separation processes, especially chemical absorption and stripping, and biochemical engineering with emphasis on engineering problems related to the growth and utilization of bacteria from extreme environments.Search for more papers by this author Gregory J. Olson, Gregory J. Olson Surface Chemistry and Bioprocesses Group, National Bureau of Standards, Gaithersburg, MD 20899 Gregory J. Olson: is currently a research microbiologist in the Institute for Materials Science and Engineering at the National Bureau of Standards in Gaithersburg, Maryland. He received a Ph.D. in Microbiology from Montana State University in 1978 and joined NBS as a National Research Council Postdoctoral Fellow (1979–81). His current research interests include biological transformations of materials and development and application of molecular measurement methods to characterize these processes.Search for more papers by this authorRobert M. Kelly, Robert M. Kelly Department of Chemical Engineering, The Johns Hopkins University, Baltimore, MD 21218 Robert M. Kelly: is currently assistant professor of chemical engineering at the Johns Hopkins University in Baltimore, Maryland where he has been since 1981. He received his BS and MS from the University of Virginia and a Ph.D. in chemical engineering from North Carolina State University. Prior to his doctoral work, he was employed with the du Pont Company at Marshall Laboratory in Philadelphia. His research interests include separation processes, especially chemical absorption and stripping, and biochemical engineering with emphasis on engineering problems related to the growth and utilization of bacteria from extreme environments.Search for more papers by this author First published: March 1986 https://doi.org/10.1002/btpr.5420020104Citations: 38 AboutPDF ToolsRequest permissionExport citationAdd to favoritesTrack citation ShareShare Give accessShare full text accessShare full-text accessPlease review our Terms and Conditions of Use and check box below to share full-text version of article.I have read and accept the Wiley Online Library Terms and Conditions of UseShareable LinkUse the link below to share a full-text version of this article with your friends and colleagues. Learn more.Copy URL Share a linkShare onEmailFacebookTwitterLinkedInRedditWechat Literature Cited 1 Torma, A. E., “Biohydrometallurgy as an emerging technology,” Biotech. Bioeng., in press. 2 Brierley, J. A., C. L. Brierley, and G. M. Goyak, “ATM—Bioclaim: A new wastewater treatment and metal recovery technology,” Proc. 6th Internat. Symp. on Biohydrometallurgy, Vancouver, BC Aug. 21–24, 1985, in press. 3 Gale, N. L. and B. G. Wixson, “Removal of heavy metals from industrial effluents by algae,” Dev. Ind. Microbiol., 20, 259 (1978). 4 Zajic, J. E., and Y. S. Chiu, “Removal of heavy metals by microbes,” Dev. Ind. Microbiol., 13, 91 (1971). 5 Temple, K. L. and A. R. Colmer, “The autotrophic oxidation of iron by a new bacterium, Thiobacillus ferrooxidans,” J. Bacteriol., 62, 605 (1951). 6 Balashava, V. I., G. E. Markosyan, and G. A. Zavarzin, “The auxotrophic growth of Leptospirillum ferrooxidans,” Microbiology, 43, 491 (1974). 7 Waksman, S. A. and J. S. Joffe, “Acid production by a new sulfur oxidizing bacterium,” Science, 53, 216 (1921). 8 Brierley, J. A., “Contribution of chemautotrophic bacteria to the acid thermal waters of the Geyser Spring Group in Yellowstone National Park,” Ph.D. thesis, Montana St. Univ., Bozeman, (1966). 9 Brock, T. D., K. M. Brock, R. T. Belly, and B. L. Weiss, “Sulfolobus: a new genus of sulfur-oxidizing bacteria living at low pH and high temperatures,” Arch. Microbiol, 84, 54 (1972). 10 Brierley, C. L. and J. A. Brierley, “A chemoautotrophic and thermophilic microorganism isolated from an acid hot spring,” Can. J. Microbiol., 19, 183 (1973). 11 Harrison, A. P. Jr., “Acidiphilium cryptum gen nov., sp. nov., heterotrophic bacterium from acidic mineral environments,” Internat. J. System. Bacteriol., 31, 327 (1981). 12 Wichlacz, P. L. and R. E. Unz, “Acidophilic heterotrophic bacteria of acid mine wastes,” Appl. Environ. Microbiol., 41, 1254 (1981). 13 Brierley, J. A., “Thermophilic iron-oxidizing bacteria found in copper leach dumps,” Appl. Environ. Microbiol., 36, 523 (1978). 14 Wood, A. P. and D. P. Kelly, “Autotrophic and mixotrophic growth of three thermoacidophilic iron-oxidizing bacteria,” Trends in Biotechnol., 3, 86 (1985). 15 Gentina, J. C. and F. Acevedo, “Microbial ore leaching in developing countries,” Trends in Biotechnol, 3, 86 (1985). 16 Ehrlich, H. L., “Inorganic energy sources for chemolithotrophic and mixotropic bacteria,” Geomicrobiol. J., 1, 65 (1978). 17 Lewis, A. J., and J. D. A. Mier, “Stannous and cuprous ion oxidation by Thiobacillus ferrooxidans,” Can. J. Microbiol., 23, 319 (1977). 18 DiSpirito, A. A. and O. H. Tuovinen, “Uranous ion oxidation and carbon dioxide fixation by Thiobacillus ferrooxidans,” Arch. Microbiol., 133, 28 (1982). 19 Kelly, D. P., Bioenergetics of chemolithotrophic bacteria, Chap. 15 in Companion to Microbiology, A. T. Bull and P. M. Meadows, eds., Longman: London and New York, pp. 363–386 (1978). 20 Ingledew, W. J., “Thiobacillus ferrooxidans: The bioenergetics of an acidophilic chemolithotroph,” Biochim. Biophys. Acta, 683, 89 (1982). 21 Ingledew, W. J. and J. G. Cobley, “A potentiometric and kinetic study on the respiratory chain of ferrous-iron-grown Thiobacillus ferrooxidans,” Biochim. Biophys. Acta, 590, 141 (1980). 22 Ingledew, W. J., “The biochemistry of ferrous iron oxidation by Thiobacillus ferrooxidans,” Biotechnol. Bioeng., in press. 23 Lyalikova, N. N., “Oxidation of trivalent antimony up to higher oxides as a source of energy for the development of a new autotrophic organism, Stibiobacter, gen. nov.,” Dokl Akad Nauk SSSR, 205, 1228 (1972). 24 Harrison, A. P. Jr., “The acidophilic thiobacilli and other acidophilic bacteria that share their habitat,” Ann Rev. Microbiol., 38, 265 (1984). 25 Golovacheva, R. S. and G. I. Karavaiko, “A new genus of thermophilic spore-forming bacteria, Sulfobacillus,” Microbiology (USSR), 47, 815 (1978). 26 Woese, C. R., L. J. Magrum, and G. E. Fox, “Archaebacteria,” J. Molecular Evolution, 11, 245 (1978). 27 Stetter, K. O., H. Konig, and E. Stackebrandt, “Pyrodictum gen nov., a new genus of submarine disc-shaped sulfur reducing archaebacteria growing optimally at 105 C,” System. Appl. Microbiol., 4, 535 (1983). 28 Speiss, F. N., et al., “East Pacific Rise: Hot Springs and Geochemical Experiments,” Science, 207, 1421 (1980). 29 Baross, J. A. and J. W. Deming, “Growth of black smoker bacteria at temperatures of at least 250 C,” Nature, 303, 423 (1983). 30 Ilyaletdinov, A. N., P. B. Enker, and L. V. Loginova, “Role of sulfate-reducing bacteria in the precipitation of copper,” Microbiology, 46, 92 (1977). 31 Manders, W. F., G. J. Olson, F. E. Brinckman, and J. M. Bellama, “A novel synthesis of methyltin triiodide with environmental implications,” J. Chem. Soc. Chem. Commun. 1984, 538 (1984). 32 Thayer, J. S., G. J. Olson, and F. E. Brinckman, “Iodomethane as a potential metal mobilizing agent in nature,” Environ. Sci. Technol., 18, 726 (1984). 33 Trimble, R. B. and H. L. Ehrlich, “Bacteriology of Manganese Nodules. IV. Induction of a MnO2 Reductase System in a Marine Bacillus,” Appl. Microbiol., 19, 966 (1970). 34 Olson, G. J. F. D. Porter, J. Rubenstein, and S. Silver, “Mercuric reductase enzyme from a mercury volatizing strain of Thiobacillus ferrooxidans,” J. Bacteriol., 151, 1230 (1982). 35 Williams, J. W. and S. Silver, “Bacterial resistance and detoxification of heavy metals,” Enzyme Microb. Technol., 6, 530 (1984). 36 Pan-Hou, H. S. and N. Imura, “Involvement of mercury methylation in microbial detoxification,” Arch. Microbiol., 131, 176 (1982). 37 Nelson, J. D., W. Blair, F. E. Brinckman, R. R. Colwell, and W. P. Iverson, “Biodegradation of phenylmercuric acetate by mercury-resistant bacteria,” Appl. Microbiol., 26, 321 (1973). 38 Silver, S. and D. Keach, “Energy dependent arsenate efflux: the mechanism of plasmid mediated resistance,” Proc. Nac. Acad. Sci. U.S.A., 79, 6114 (1982). 39 Blakemore, R. P. “Magnetotactic bacteria,” Ann. Rev. Microbiol., 36, 217 (1982). 40 Bennett, J. C. and H. Tributsch, “Bacterial leaching patterns on pyrite crystal surfaces,” J. Bacteriol., 134, 310 (1978). 41 Kelly, D. P., P. R. Norris, and C. L. Brierly, Microbiological methods for the extraction and recovery of metals, in Microbiol technology: current state, future prospects, A. T. Bull, D. C. Ellwood, and C. Ratledge, eds., Cambridge Univ. Press, Cambridge, pp. 263–308 (1979). 42 Singer, P. C. and W. Stumm, “Acidic mine drainage: the rate-determining step,” Science, 167, 1121 (1970). 43 Mehta, A. P., A. E. Torma, and L. E. Murr, “Biodegradation of aluminum bearing rocks by Penicillium simplicissimum,” IRCS Med. Sci. Biochem.; Environ. Biol. Med., Microbiol., Parasit. Infect. Diseases, 6, 416 (1978). 44 Banik, S. and B. K. Dey, “Alluvial soil microorganisms capable of utilizing insoluble aluminum phosphate as a sole source of phosphorus,” Zbl. Mikrobiol., 138, 437 (1983). 45 Siegel, S. M., B. Z. Siegel, and K. E. Clark, “Bio-corrosion: solubilization and accumulation of metals by fungi,” Water, Air, Soil Pollut., 19, 229 (1983). 46 Torma, A. E., “Current standing of bacterial heap, dump, and in-situ leaching technology of copper,” Metall., 38, 1044 (1984). 47 McCready, R. G. L., D. Wadden, and A. Marchbank, “Optimization of the bacterial leaching of uranium,” Paper presented at Workshop on Biotechnology for the Mining, Metal-Refining, and Fossil Fuel Processing Industries, Troy, NY, May 28–30 (1985). 48 Lawrence, R. W. and A. Bruynesteyn, “Biological pre-oxidation to enhance gold and silver recovery from refractory pyritic ores and concentrates,” CIM Bull., 76, 107 (1983). 49 Silverman, M. P., M. H. Rogoff, and I. Wender, “Removal of pyritic sulphur from coal by bacterial action,” Fuel, 42, 113 (1963). 50 Torma, A. E. and L. E. Murr, “Desulfurization of coal by microbiological leaching,” New Mexico Energy and Minerals Department Rep. No. EMD-2-67-3319, Santa Fe (1981). 51 Myerson, A. S. and P. C. Kline, “Continuous bacterial coal desulfurization employing Thiobacillus ferrooxidans,” Biotechnol. Bioeng., 26, 92 (1984). 52 Detz, C. M. and G. Barvinchak, “Microbiol desulfurization of coal,” Mining Congress J., 65, 75 (1979). 53 Kargi, F. and J. G. Weissman, “A dynamic mathematical model for microbial removal of pyritic sulfur from coal,” Biotechnol. Bioeng., 26, 604 (1984). 54 Kargi, F. and J. M. Robinson, “Biological removal of pyritic sulfur from coal by the thermophilic organism Sulfolobus acidocaldarius,” Biotechnol. Bioengin., 27, 41 (1985). 55 Chandra, D., P. Roy, A. K. Mishra, J. N. Chakrabarti, and B. Sengupta, “Microbial removal of organic sulfur from coal,” Fuel, 58, 549 (1979). 56 Kargi, F. and J. M. Robinson, “Microbial desulfurization of coal by the thermophilic microorganism, Sulfolobus acidocaldarius,” Biotechnol. Bioeng., 24, 2115 (1982). 57 Gockay, C. F. and R. N. Yurteri, “Microbial desulfurization of lignites by a thermophilic bacteria,” Fuel, 62, 1223 (1983). 58 Atlantic Research Corp., “Pseudomonas for desulfurization of fossil fuels,” U.S. Patent Application 512,857, July 11, 1983. 59 Kargi, F., “Microbial oxidation of dibenzothiophene by the thermophilic organism Sulfolobus acidocaldarius,” Biotechnol. Bioeng., 26, 687 (1984). 60 Monticello, D. J. and W. R. Finnerty, “Microbial desulfurization of fossil fuels,” Annu. Rev. Microbiol., 39, 371 (1985). 61 Bosecker, K., “Metal recovery and detoxification of industrial waste products,” Biotechnol. Bioengin., in press. 62 Beveridge, T. J., “Ultrastructure, chemistry, and function of the bacterial wall,” Int. Rev. Cytol., 72, 229 (1981). 63 Volesky, B., “Biosorbent materials,” Biotechnol. Bioeng., in press. 64 Dunn, G. M. and A. T. Bull, “Bioaccumulation of copper by a defined community of activated sludge bacteria,” Eur. J. Appl. Microbiol. Biotechnol., 17, 30 (1983). 65 Charley, R. C. and A. T. Bull, “Bioaccumulation of silver by a multispecies community of bacteria,” Arch. Microbiol., 123, 239 (1979). 66 Nakajima, A., T. Horikoshi, and T. Sakaguchi, “Recovery of uranium by immobilized microorganisms,” Eur. J. Appl. Microbiol. Biotechnol., 16, 88 (1982). 67 Brierley, J. A., Biological accumulation of some heavy metals—biotechnological applications. in Biomineralization and Biological Metal Accumulation, P. Westbrock and E. W. de Jong, eds., D. Reidel Publ. Co., pp. 499–509 (1983). 68 Wood, J. M. and H. K. Wang, “Strategies for microbial resistance to heavy metals,” in Chemical Processes in Lakes, W. Stumm, ed., pp. 81–97 (1985). 69 Monroe, D., “Microbial metal mining,” American Biotechnol. Lab., p. 10, January/February (1985). 70 Brierley, C. L., “Bacterial leaching,” CRC Crit. Rev. Microbiol., 6, 207 (1978). 71 Ralph, B. J., “Geomicrobiology and the new biotechnology,” Dev. Ind. Microbiol., 27, 850 (1985). 72 Torma, A. E., C. C. Walden, D. W. Duncan, and R. M. R. Branion, “The effect of carbon dioxide and particle surface area on the microbiological leaching of a zinc concentrate,” Biotechnol. Bioeng., 14, 777 (1972). 73 McElroy, R. O. and A. Bruynesteyn, Continuous biological leaching of chalcopyrite concentrates: Demonstration and economic analysis, in Metallurgical Applications of Bacterial Leaching and Related Microbiological Phenomena, L. E. Murr, A. E. Torma, and J. A. Brierley, eds., pp. 441–462, Academic Press, New York (1978). 74 Babij, T. and B. J. Ralph, “Assessment of metal recovery and metal pollution potentiality of sulphidic mine wastes,” Proc. GIAM V, pp. 476–479 (1979). 75 Babij, T., R. B. Noble, and B. J. Ralph, A reactor system for mineral leaching investigations, in Biogeochemistry of Ancient and Modern Environments, P. A. Trudinger, M. R. Walter, and R. B. Ralph, eds., pp. 563–572 (1980). 76 Sanmugasunderam, V., “The continuous microbiological leaching of zinc sulphide concentrate with recycle,” Ph.D. Thesis, Univ. British Columbia (1981). 77 Rai, C., “Microbial desulfurization of coals in a slurry pipeline reactor using Thiobacillus ferrooxidans,” Biotechnol. Prog., 1, 200 (1985). 78 Yukawa, T., “Mass transfer studies in microbial systems,” Ph.D. Thesis, Univ. of South Wales (1975). 79 Ebner, H. G., Bacterial leaching in an airlift reactor, in Proc. Int. Conf. on Use of Micro-organisms in Hydrometallurgy, Hungarian Academy of Sciences, B. Czegledi, ed., pp. 211–217 (1980). 80 Kiese, S., H. G. Ebner, and U. Onken, “A simple laboratory airlift fermentor,” Biotechnol. Lett., 2, 345 (1980). 81 Livesey-Goldblatt, E., T. H. Tunley, and I. F. Nagy, Pilot-plant bacterial film oxidation (Bacfoc Process) of recycled acidified uranium plant ferrous sulphate leach solution, in CBF Monograph Series, No. 4, Conference on Bacterial Leaching, W. Schwartz, ed., pp. 175–190, Verlag Chemie, Weinham (1977). 82 Atkins, A. S. and F. D. Pooley, Comparison of bacterial reactors employed in the oxidation of sulphide concentrates, in Recent Progress in Hydrometallurgy, pp. 111–125, G. Rossi and A. E. Torma, eds., Associazione Mineraria Sarda-09016 Iglesias-Italy (1983). 83 Huber, T. F., C. H. Kos, P. Bos, N. W. F. Kossen, and J. G. Kuenen, Modelling, scale-up and design of bioreactors for microbial desulphirization of coal, in Recent Progress in Hydrometallurgy, pp. 279–289, G. Rossi and A. E. Torma, eds., Op. cit. 84 Zajic, J. E., Microbial Biogeochemistry, Academic Press, New York (1969). 85 Lawrence, R. W., A. Vizsolyi, R. J. Vos, and A. Bruynesteyn, Continuous bioleaching of copper concentrates, AIChE National Meeting, Atlanta, Georgia (1984). 86 Myerson, A. S. and P. C. Kline, “The adsorption of Thiobacillus ferrooxidans on solid particles,” Biotechnol. Bioeng., 25, 1669 (1983). 87 DiSpirito, A. A., P. R. Dugan, and O. H. Tuovinen, “Sorption of Thiobacillus ferrooxidans to particulate materials,” Biotechnol. Bioeng., 25, 1163 (1983). 88 Erickson, L. E., L. T. Fan, P. S. Shah, and M. S. K. Chen, “Growth models of cultures with two liquid phases: IV. Cell adsorption, drop size distribution, and batch growth,” Biotechnol. Bioeng., 12, 713 (1970). 89 Gormely, L. S., D. W. Duncan, R. M. R. Branion, and K. L. Pinder, “Continuous culture of Thiobacillus ferrooxidans on a zinc sulfide concentrate,” Biotechnol. Bioeng., 17, 31 (1975). 90 Sanmugasunderam, V., R. M. R. Branion, and D. W. Duncan, “A growth model for the continuous microbiological leaching of a zinc sulfide concentrate by Thiobacillus ferrooxidans,” Biotechnol. Bioeng., 27, 1173 (1985). 91 Chang, Y. C. and A. S. Myerson, “Growth models of the continuous bacterial leaching of iron pyrite by Thiobacillus ferrooxidans,” Biotechnol. Bioeng., 24, 889 (1982). 92 Yeh, T. Y., J. R. Godshalk, G. J. Olson, and R. M. Kelly, “Use of epifluorescence microscopy for characterizing the activity of Thiobacillus ferrooxidans on metal sufides,” submitted to Biotechnol. Bioeng. 93 Lancy, E. D., and O. H. Tuovinen, “Ferrous ion oxidation by Thiobacillus ferrooxidans in calcium alginate,” Appl. Microbiol. Biotechnol., 20, 94 (1984). 94 Kelly, D. P., C. A. Jones, and J. S. Green, “Factors affecting metabolism and ferrous iron oxidation in suspensions and batch cultures of Thiobacillus ferrooxidans,” paper presented at Int. Symp. Metallurg. Appl. Bacterial Leaching and Related Microbial Phenomena, Socorro, New Mexico, August, 1977. 95 Guay, R., M. Silver, and A. E. Torma, “Ferrous iron oxidation and uranium extraction by Thiobacillus ferrooxidans,” Biotechnol., Bioeng., 19, 727 (1977). 96 Liu, M. S., R. M. R. Branion, and D. W. Duncan, “Determination of the solubility of oxygen in fermentation media,” Biotechnol. Bioeng., 15, 213 (1973). 97 Tuovinen, O. H. and D. P. Kelly, “Biology of Thiobacillus ferrooxidans in relation to the microbiological leaching of sulphide ores,” Z. Allg. Mikrobiol., 12, 311 (1972). 98 Schumpe, A., G. Quicker, and W.-D. Deckwer, Gas solubilities in microbial culture media, in Advances in Biochemical Engineering, Volume 24: Reaction Engineering, A. Fiechter, ed., Springer-Verlag, Berlin-Heidelberg (1982). 99 Le Roux, N. W. and V. M. Marshall, Effect of Light on Thiobacilli, presented at Round Table Conf. on Leaching, Braunschweif, Germany, March 27-April 2, 1977. 100 Yunker, S. B. and J. M. Rodavich, “Electrolytically enhanced growth of Thiobacillus ferrooxidans,” presented at Wkshp on Biotech. for the Mining, Metal-Refining, and Fossil Fuel Proc. Industries, Poster #1, Troy, NY, May 28–30 (1985). 101 Kinsel, N. A. and W. W. Umbreit, “Method of electrolysis of culture medium to increase growth of the sulfur-oxidizing iron bacterium Ferrobacillus sulfooxidans,” J. Bacteriol., 94, 1046 (1967). 102 Davidson, M. A. and A. O. Summers, “Wide-range host plasmids function in the genus Thiobacillus,” Appl. Environ. Microbiol., 46, 565 (1983). 103 Brierley, C. L., “Microbiological mining,” Sci. Am., 247, 44 (1982). 104 Beveridge, T. J., “The immobilization of soluble metals by bacterial walls,” Biotechnol. Bioeng., in press. 105 Martin, P. A., P. Dugan, and O. H. Tuovinen, “Plasmid DNA in acidophilic, chemolithotrophic thiobacilli,” Can. J. Microbiol., 27, 850 (1981). 106 Rawlings, D. E., I. M. Pretorius, and D. R. Woods, “Construction of arsenic-resistant Thiobacillus ferrooxidans recombinant plasmids and the expression of autotrophic plasmid genes in a heterotrophic cell-free system,” J. Biotechnol., 1, 129 (1984). 107 Kulpa, C. F., M. T. Roskey, and M. J. Travis, “Transfer of plasmid RPI into chemolithotrophic Thiobacillus neapolitanus,” J. Bacteriol., 156, 434 (1983). 108 Woods, D. and D. Rawlings, “Molecular genetic studies on the thiobacilli and the development of improved biomining bacteria,” BioEssays, 2, 8 (1985). 109 Bosecker, K., A. E. Torma, and J. A. Brierley, “Microbiological leaching of a chalcopyrite concentrate and the influence of hydrostatic pressure on the activity of Thiobacillus ferrooxidans, Eur. J. Appl. Microbiol., 7, 85 (1979). 110 Davidson, M. S., A. E. Torma, J. A. Brierley, and C. L. Brierley, “Effects of elevated pressures on iron- and sulfur-oxidizing bacteria,” Biotechnol. Bioeng., Symp. No. 11, 603 (1981). 111 Davidson, M. S., “The effects of simulated deep simulation mining conditions on the activity of iron and sulfur oxidizing bacteria,” Ph.D. Thesis, New Mexico Inst. of Mining and Technology, Socorro, New Mexico (1982). 112 Sturm, F. J., S. A. Hurwitz, J. W. Deming, and R. M. Kelly, “Growth of the extreme thermophile, Sulfolobus acidocaldarius, in a hyperbaric helium bioreactor,” submitted to Biotechnol. Bioeng. 113 Hurwitz, S. A., “Effect of temperature and pressure on the growth of Sulfolobus acidocaldarus,” Masters Thesis, Dept. of Chem. Eng., The Johns Hopkins Univ. (1985). 114 Deming, J. W., The biotechnological future for newly-described, extremely thermophilic bacteria, in Microbial Ecology, special issue devoted to Biotechnology, R. R. Colwell and A. L. Demain, eds., Springer-Verlag, in press. 115 Hurwitz, S. A., F. J. Sturm, J. W. Deming, and R. M. Kelly, “The effect of temperature and pressure on the growth of extremely thermophilic bacteria,” presented at the 77th Ann. Mtg. of the Am. Inst. Chem. Eng., Chicago, III., November, 1985. Citing Literature Volume2, Issue1March 1986Pages 1-15 ReferencesRelatedInformation DA - 1986/3// PY - 1986/3// DO - 10.1002/btpr.5420020104 VL - 2 IS - 1 SP - 1-15 J2 - Biotechnol Progress LA - en OP - SN - 8756-7938 1520-6033 UR - http://dx.doi.org/10.1002/btpr.5420020104 DB - Crossref ER - TY - CHAP TI - Stratification and Differentiation Within Smallholder Strata: A North Carolina Case Study AU - Schulman, Michael D. AU - Garrett, Patricia T2 - Farming Systems Research and Extension: Implementation and Monitoring A2 - Flora, Cornelia Butler A2 - Tomecek, Martha PY - 1986/// SP - 557–71 PB - Kansas State University ER - TY - CHAP TI - Factors in the Success and Survival of Smallholders: A North Carolina Case Study AU - Schulman, Michael D. AU - Greene, Jody T2 - Agricultural Change A2 - Molnar, Joseph J. PY - 1986/// DO - 10.4324/9780429040641-10 SP - 201-222 PB - Routledge SN - 9780429040641 UR - http://dx.doi.org/10.4324/9780429040641-10 ER - TY - JOUR TI - Economic Injury Level, Action Threshold, and a Yield-loss Model for the Pea Aphid, Acyrthosiphon pisum (Homoptera: Aphididae), on Green Peas, Pisum sativum AU - Yencho, G. C. AU - Getzin, L. W. AU - Lono, Garrell E. T2 - Journal of Economic Entomology AB - Economic injury level, action threshold, and population development studies with the pea aphid (PA), Acyrthosiphon pisum (Harris), were conducted during 1983–85. Pea aphid densities, simulating those in commercial pea fields, were established using insecticides to manipulate infestation levels. Three experiments, incorporating 12 treatments and six replications, were analyzed. A generalized, nonlinear equation relating pea yield to accumulated aphid feeding days (AFD) is described. The model approximates two phases of a sigmoid infestation-yield curve. An upper maximum plateau and a region of rapidly decreasing yield are approximated. Beyond 1,800 AFD, a lower minimum yield plateau is hypothesized. Economic injury levels calculated for the 3 years’ experiments using the generalized model were 22.2, 18.2, and 12.2 AFD, respectively. Action threshold estimates were determined from linear regression estimates of yield versus aphids per plant at bloom. Action thresholds were 3.6, 0.3, and 0.3 aphids per plant for the years 1983, 1984, and 1985, respectively. The pea quality components, tenderometer (TD) and sieve size, were altered by maximum PA densities. High AFD levels increased TD and decreased sieve size significantly when compared with aphid-free controls. Protein content of green peas was not significantly altered by PA feeding. DA - 1986/// PY - 1986/// DO - 10.1093/jee/79.6.1681 VL - 79 IS - 6 SP - 1681-1687 ER - TY - JOUR TI - Reasons for Changes in Meat Consumption Composition AU - Thurman, Walter N. AU - Standaert, James E. T2 - Tar Heel Economist DA - 1986/2// PY - 1986/2// VL - 2 N1 - newspaper article RN - newspaper article ER - TY - SOUND TI - Have Meat Price and Income Elasticities Changed? Their Connection with Changes in Marketing Channels AU - Thurman, Walter N. DA - 1986/10// PY - 1986/10// N1 - Sponsored by The Southern Regional Research Committee (S-165) and the Board of Agriculture of the National Research Council RN - Sponsored by The Southern Regional Research Committee (S-165) and the Board of Agriculture of the National Research Council ER - TY - JOUR TI - Endogeneity Testing in a Supply and Demand Framework AU - Thurman, Walter N. T2 - The Review of Economics and Statistics AB - The powers of Wu-Hausman endogeneity tests are related to the normalization d ecision in estimating demand equations. Power is not invariant to the choice bet ween quantity and price as the dependent variable. A theoretical result due to N akamura and Nakamura_(1984) is used to explore the dependence of power on parame ters of the supply and demand system. The theoretical result is corroborated wit h a Monte Carlo experiment. The power results are used to analyze the U.S. deman d for poultry meat wherein price, but not quantity, is found to be predetermined Copyright 1986 by MIT Press. DA - 1986/11// PY - 1986/11// DO - 10.2307/1924523 VL - 68 IS - 4 SP - 638 ER - TY - CONF TI - Research on new barrier testing approaches AU - McCord, M.G. A2 - R. L. Barker, A2 - Coletta, G. C. C2 - 1986/// C3 - Performance of protective clothing: a symposium sponsored by ASTM Committee F-23 on Protective Clothing, Raleigh, NC, 16-20 July 1984 DA - 1986/// PB - Philadelphia, PA: ASTM SN - 9780803104617 ER - TY - CONF TI - Introduction to testing of chemical and biological barriers AU - McCord, M.G. A2 - R. L. Barker, A2 - Coletta, G. C. C2 - 1986/// C3 - Performance of protective clothing: a symposium sponsored by ASTM Committee F-23 on Protective Clothing, Raleigh, NC, 16-20 July 1984 DA - 1986/// PB - Philadelphia, PA: ASTM SN - 9780803104617 ER -