Recognition biological

There is quite a large body of literature on films of biological substances and related model compounds, much of it made possible by the sophisticated microscopic techniques discussed in Section IV-3E. There is considerable interest in biomembranes and how they can be modeled by lipid monolayers [35]. In this section we briefly discuss lipid monolayers, lipolytic enzyme reactions, and model systems for studies of biological recognition. The related subjects of membranes and vesicles are covered in the following section. [Pg.544]

Carbohydrate mimetics including heterocyclic fragments and a new strategy for tackling the problem of biological recognition with participation of carbohydrates 99AG(E)2300. [Pg.224]

The present review intends to be illustrative rather than comprehensive, and focuses on the results of this study leading to the hypothesis 9 — the three-dimensional shape similarity between interacting groups in reacting molecules is responsible for more specific and precise molecular recognition than would otherwise be achieved — and on the explanation of biological recognition on this basis. [Pg.92]

Electrochemical biosensors combine die analytical power of electrochemical techniques with the specificity of biological recognition processes. The aim is to... [Pg.171]

Background current, 21, 65 Background subtraction, 40, 106 Bacteria electrode, 182 Band microelectrodes, 130, 135 Beryllium, 82 Bienzyme electrodes, 175 Biocatalytic devices, 172 Biological recognition, 171 Biosensors, 50, 171 Bipotentiostat, 106 Blood electrolyte, 165 Boltzmann equation, 19 Brain analysis, 40, 116 Butler-Volmer equation, 14... [Pg.205]

Biosensors play a significant role in the monitoring of a wide range of diseases and pathogens. A biosensor is an analytical device, which incorporates a biological recognition element or bioreceptor which is capable of sensing the presence. [Pg.339]

Schulz, G. E. (1979). In Molecular Mechanism of Biological Recognition (M. Balaban, ed.), pp. 79-94. Elsevier/North-Holland Biomedical Press, New York. [Pg.71]

Meyer, E.A., Castellano, R.K. and Diederich, F. (2003) Interactions with aromatic rings in chemical and biological recognition. Angewandte Chemie International Edition, 42 (11), 1210-1250. [Pg.279]

Yu, L., Banerjee, I.A. and Matsui, H. (2003) Direct growth of shape-controlled nanocrystals on nanotubes via biological recognition. Journal of the American Chemical Society, 125, 14837-14840. [Pg.185]

Chaiken, I.M., Wilchek, M., and Parikh, I. (eds.) (1983) Affinity Chromatography and Biological Recognition, p. 173. Academic Press, San Diego. [Pg.1053]

Hearn, M.T.W., Smith, P.K., Mallia, A.K., and Hermanson, G.T. (1983) Preparative and analytical applications of CDI-mediated affinity chromatography. In Affinity Chromatography and Biological Recognition, pp. 191-196. Academic Press, New York. [Pg.1072]

A biosensor is an analytical device comprising a biological recognition element directly interfaced to a signal transducer, which together relates the concentration of... [Pg.555]

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