Bioengineering

Richards F M 1977. Areas, Volumes, Packing and Protein Structure. Annual Review in Biophysics ana Bioengineering 6 151-176. [Pg.45]

D. Burrows, Eiterature Eeview of the Toxicity ofEDX and HMX, U.S. Army Medical and Bioengineering Research and Development Lab., Washington, D.C., 1973. [Pg.28]

Methods to control infiltration of water into low level waste disposal faciUties are being studied. Three techniques that may be employed separately, in sequence, or in conjunction are use of a resistive layer, eg, clay use of a conductive layer, involving wick action and bioengineering, using a special plant cover. [Pg.232]

An interesting biochemical method of manufacture is the utili2ation of bioengineered Fseudomonad 2isrmA (16) or Pseudomonas stut ri (17) in a culture medium to oxidi2e naphthalene or alkyl-substituted naphthalene. The metabohc oxidation products, unsubstituted or substituted sahcyhc acid. [Pg.286]

J. R. Dooley and D. D. Lineberry, in Symposium on Neir Depelopments in Bioengineering—Minneapolis, preprint, American Institute of Chemical Engineering, New York, 1965, 12 pp. [Pg.411]

Mavrovouniotis, M. L., and Stephanopoulos, G. (1990). Computer-aided synthesis of biochemical pathways. Biotechnology and Bioengineering, 36, 1119-1132. [Pg.295]

Petanate, A.M. and Glatz, C.E., 1983. Isoelectric precipitation of soy protein. I. Factors affecting particle size distributions. II. Kinetics of protein aggregate growth and breakage. Biotechnology and Bioengineering, 25, 3049. [Pg.318]

Petsko, G. A., and Ringe, D., 1984. Fluctuations in protein structure from X-ray diffraction. Annual Review of Biophysics and Bioengineering 13 331 —371. [Pg.208]

Steitz, T, and Shulman, R., 1982. Cry.stallographic and NMR. studies of the serine proteases. Annual Review of Biophysics and Bioengineering 4.4.4.. [Pg.532]

Hensten-Pettersen, A. and Jacobsen, N. Nickel Corrosion of Non-precious Casting Alloys and the Cytotoxic Effect of Nickel In Vitro , Journal of Bioengineering, 2, 419-425 (1978)... [Pg.467]

Worldwide suppliers with bioengineering capabilities are displacing established polymers with cost-effective and higher performing plastics. An explosion of novel polymers has been made by enzymatic control. The use of enzymes for polymerization has drastically altered the landscape of polymer chemistry. Processors can request specific properties for each application as opposed to the usual making do with what is available. The supplier can deliver to the processor desired properties requested. [Pg.373]

L. B. Wingard Jr., E. Katchalski-Katzir u. L. Goldstein, Applied Biochemistry and Bioengineering, Vol. 1 Immobilized Enzyme Principles, Academic Press, New York 1976. [Pg.787]

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