Molecular recognition and

A Biosensor is a device where a coupling has been realized between a biological element responsible for the molecular recognition and tire element responsible for the transduction of the signal. 

Molecular recognition and the quest for new catalysts in combinatorial syntheses with participation and formation of heterocycles 97LA637. 

Macroheterocyclic systems with 1,1 -binaphthyl fragments in molecular recognition and asymmetric catalysis 98CRV2405. 

N. Guzman, On-line bioaffinity, molecular recognition and preconcenti ation in CE technology , EC-GC, 17 16 (1999). 

Paldus J, Li X (1999) Electron Correlation in Small Molecules Grafting Cl onto CC. 203 1-20 Paleos CM, Tsiourvas D (2003) Molecular Recognition and Hydrogen-Bonded Amphiphilies. 227 1-29... 

Proteins derive their powerful and diverse capacity for molecular recognition and catalysis from their ability to fold into defined secondary and tertiary structures and display specific functional groups at precise locations in space. Functional protein domains are typically 50-200 residues in length and utilize a specific sequence of side chains to encode folded structures that have a compact hydrophobic core and a hydrophilic surface. Mimicry of protein structure and function by non-natural ohgomers such as peptoids wiU not only require the synthesis of >50mers with a variety of side chains, but wiU also require these non-natural sequences to adopt, in water, tertiary structures that are rich in secondary structure. 

Efforts to investigate the questions posed here will lead to more useful peptoid designs while simultaneously leading to a better fundamental understanding of molecular recognition and sequence/structure/function relationships in non-natural, sequence-specific peptidomimetic ohgomers. 

Paleos CM, Tsiourvas D (2003) Molecular Recognition and Hydrogen-Bonded Amphi-philies. 227 1-29... 

Brooijmans N, Knntz ID. Molecular recognition and docking algorithms. Anna Rev Biophys Biomol Struct 2003 32 335-73. 

McLendon, G. Control of Biological Electron Transport via Molecular Recognition and Binding The Velcro Model. Vol. 75, pp. 159-174. 

Houk RJT, Tobey SL, Anslyn EV (2005) Abiotic Guanidinium Receptors for Anion Molecular Recognition and Sensing. 255 199-229 Hue I, see Brizard A (2005) 256 167-218... 

Reports of molecular recognition and self-assembly aspects of supramolecular chemistry associated with dendrimers and related structures will be the chief focus of this review. 

As will be demonstrated, surface branching has afforded a series of dendri-mers lacking site-specific [31-33] characteristics whereas, the use of branched monomers has the unique ability to instill tailored loci capable of site-specific molecular recognition and encapsulation. 

These (weak) interactions in particular lead to molecular recognition and thus to replication and self-replication while they lead relatively easily to bonding, the bonds formed can, however, just as easily be broken again (Rebek, 1990, 1994). 

Our discussion in this chapter will focus on the use of the electrostatic potential as a means to understanding and predicting chemical interactions. First, we will examine some of its properties and important features. Next, we will discuss methodology. Finally we will review some recent applications of the electrostatic potential in areas such as hydrogen bonding, molecular recognition, and understanding and prediction of a variety of physio-chemical properties related to molecular interactions. Our intent has not been to provide a complete survey of the ways in which the potential has been used, many of which are described elsewhere (Politzer and Daiker 1981 Politzer, Laurence, and Jayasuriya 1985 Politzer and Murray 1990 Politzer and Murray 1991 Politzer and Truhlar 1981 Scrocco and Tomasi 1973), but rather to focus on some diverse examples. 

Kieffer BL. Recent advances in molecular recognition and signal transduction of active peptides receptors for opioid peptides. Cell Mol Neurobiol 1995 15 615— 635. 

Fig. 4.28 Cate-controlled molecular recognition and fluorescence detection by selective functionalization of external and internal surfaces of mesoporous silicates. Reprinted with permission from [225], R. D. Radu et al.,J. Am. Chem. Soc. 2004, 126, 1640. 2004, American Chemical Society.

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