Physics And Chemistry Basis Of Biotechnology - De Cuyper - tiera.ru

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Supported lipid membranes for reconstitution of membrane proteins 88. Florin, E.-L. and Gaub, H.E. (1993) Painted supported lipid membranes, Biophys. J. 64,375-383. 89. Salamon, Z. and Tollin, G. (1997) Interaction of horse heart cytochrome c with lipid bilayer membranes: Effects on redox potentials, J. Bioenerg. Biomembr. 29,211-221. 90. Terrettaz, S., Vogel, H. and Gratzel, M. (1998)Determination of the surface concentration of crown ethers in supported lipid membranes by capacitance measurements, Langmuir 14,2573-2576. 91. Tien, H.T. and Salamon, Z. (1989) Formation of self-assembled lipid bilayers on solid substrates, Bioelectrochem. Bioenerg. 22,211-218. 92. Tien, H.T. and Ottova, A.L.(1999) From self-assembled bilayer lipid membranes (BLMs) to supported BLMs on metal and gel substrates to practical applications, Colloid Surface A 149, 217-233. 93. Ottova, A,, Tvarozek, V., Racek, J., Sabo, J., Ziegler, W., Hianik, T. and Tien, H.T. (1997) Selfassembled BLMs: biomembrane models and biosensor applications, Supramol. Sci. 4, 101-1 12. 94. Tien, H.T. and Ottova, A.L. (1998) Supported planar lipid bilayers (s-BLMs) as electrochemical biosensors, Electrochim. Acta 43, 3587-3610. 95. Tien, H.T., Barish, R.H., Gu, L.Q. and Ottova, A.L. (1998) Supported bilayer lipid membranes as ion and molecular probes, Analyt. Sci. 14, 3-18. 96. Tien, H.T., Wurster, S.H. and Ottova, A.L. (1997) Electrochemistry of supported bilayer lipid membranes: Background and techniques for biosensor development, Bioelectrochem. Bioenerg. 42, 77-94. 97. Siontorou, C.G., Nikolelis, D.P. and Krull, U.J. (1997) A carbon dioxide biosensor based on haemoglobin incorporated in metal supported bilayer lipid membranes (BLMs): Investigations for enhancement of response characteristics by using platelet- activating factor, Electroanalysis 9, 1043- 1048. 98. Rehak, M., Snejdarkova, M. and Hianik, T. (1997) Acetylcholine minisensor based on metal-supported lipid bilayers for determination of environmental pollutants, Electroanalysis 9, 1072-1077. 99. Hianik, T., Kaatze, U., Sargent, D.F., Krivanek, R., Halstenberg, S., Pieper, W., Gaburjakova, J., Gaburjakova, M., Pooga, M. and Langel, U. (1997) A study of the interaction of some neuropeptides and their analogs with bilayer lipid membranes and liposomes, Bioelectrochem. Bioenerg. 42, 123- 132. 100. Duschl, C., Liley, M., Corradin, G. and Vogel, H. (1994) Biologically addressable monolayer structures formed by templates of sulphur-bearing molecules., Biophys. J. 67, 1229-1237. 101. Duschl, C., Liley, M. and Vogel, H. (1994) Micrometer-Scale lateral structuring of organic thiolate layers through self-organisation, Angew. Chem. Int. Ed. Engl. 33, 1274-1276. 102. Jenkins, A.T.A., Boden, N., Bushby, R.J., Evans, S.D., Knowles, P.F., Miles, R.E., Ogier, S.D., Schonherr, H. and Vancso, G.J. (1999) Microcontact printing of lipophilic self-assembled monolayers for the attachment of biomimetic lipid bilayers to surfaces, J. Am. Chem. SOC. 121, 5274-5280. 103. Jenkins, A.T.A., Bushby, R.J., Boden, N., Evans, S.D., Knowles, P.F., Liu, Q.Y., Miles, R.E. and Ogier, S.D. (1998) Ion-selective lipid bilayers tethered to microcontact printed self-assembled monolayers containing cholesterol derivatives, Langmuir 14,4675-4678. 104. Steinem, C., Janshoff, A,, von dem Bruch, K., Reihs, K., Goossens, J. and Galla, H.J. (1998) Valinomycin-mediated transport of alkali cations through solid supported membranes, Bioelectrochem. Bioenerg. 45, 17-26. 105 Naumann, R., Jonczyk, A,, Kopp, R., Esch, J.v., Ringsdorf, H., Knoll, W. and Gräber, P. (1995) Incorporation of membrane proteins in solid supported lipid layers, Angew. Chem. Int. Ed. Engl. 34, 2056-2058. 106. Bunjes, N., Schmidt, E.K., Jonczyk, A,, Rippmann, F., Beyer, D., Ringsdorf, H., Graber, P., Knoll, W. and Naumann, R. (1997) Thiopeptide-supported lipid layers on solid substrates, Langmuir 13, 6188- 6194. 107. Naumann, R., Jonczyk, A,, Hampel, C., Ringsdorf, H., Knoll, W., Bunjes, N. and Graber, P. (1997) Coupling of proton translocation through ATPase incorporated into supported lipid bilayers to an electrochemical process, Bioelectrochem. Bioenerg. 42, 241 -247. 108. Schmidt, E.K., Liebermann, T., Kreiter, M., Jonczyk, A,, Naumann, R., Offenhausser, A,, Neumann, E., Kukol, A,, Maelicke, A. and Knoll, W. (1998) Incorporation of the acetylcholine receptor dimer from Torpedo californica in a peptide supported lipid membrane investigated by surface plasmon and fluorescence spectroscopy, Biosens. and Bioelectron. 13, 585-591. 163
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PHYSICS AND CHEMISTRY BASIS OF BIOT
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Physics and Chemistry Basis of Biot
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EDITORS PREFACE At the end of the 2
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TABLE OF CONTENTS EDITORS PREFACE .
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4.3. Expression and functionality .
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2 . Magnetically labelled antibodie
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6.1. Instrumental characterisation
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BIOMIMETIC MATERIALS SYNTHESIS Abst
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Biomimetic materials synthesis cont
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Biomimetic materials synthesis 3. I
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Biomimetic materials synthesis The
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Biomimetic materials synthesis 3.2.
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Biomimetic materials synthesis 3.5.
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Biomimetic materials synthesis In t
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Biomimetic materials synthesis The
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Biomimetic materials synthesis Othe
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Biomimetic materials synthesis on s
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Biomimetic materials synthesis form
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Biomimetic materials synthesis poly
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Biomimetic materials synthesis anal
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Biomimetic materials synthesis Figu
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Biomimetic materials synthesis Sinc
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Biomimetic materials synthesis inte
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Biomimetic materials synthesis 42.
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DENDRIMERS: Chemical principles and
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Dendrimers: Chemical principles and
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RATIONAL DESIGN OF P450 ENZYMES FOR
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Rational design of P450 enzymes for
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AMPEROMETRIC ENZYME-BASED BIOSENSOR
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Amperometric enzyme-based biosensor
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Page 120 and 121: Amperometric enzyme-based biosensor
Page 138 and 139: SUPPORTED LIPID MEMBRANES FOR RECON
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Page 184 and 185: COLD-ADAPTED ENZYMES D. GEORLETTE,
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Page 190 and 191: Cold-adapted enzymes flexibility of
Page 192 and 193: Cold-adapted enzymes Some recent wo
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Page 198 and 199: Cold-adapted enzymes 16. Gilichinsk
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Page 202 and 203: Cold-adapted enzymes 101. Yip, K. S
Page 204 and 205: MOLECULAR AND CELLULAR MAGNETIC RES
Page 206 and 207: Molecular and cellular magnetic res
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RADIOACTIVE MICROSPHERES FOR MEDICA
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Radioactive microspheres for medica
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RADIATION-INDUCED BIORADICALS: Phys
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Radiation-induced bioradicals: phys
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RADIATION-INDUCED BIORADICALS: Tech
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Radiation-induced bioradicals: tech
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References Radiation-induced biorad
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AROMA MEASUREMENT: Recent developme
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Aroma measurement: recent developme
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62 63 64 65 66 67 68 69 70 71 72 73
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INDEX albumin.... 122,151, 198, 206
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frog embryo .......................
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P-32 ..............................
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