Combinatorial chemistry preparation

Memfield s concept of a solid phase method for peptide synthesis and his devel opment of methods for carrying it out set the stage for an entirely new way to do chem ical reactions Solid phase synthesis has been extended to include numerous other classes of compounds and has helped spawn a whole new field called combinatorial chemistry Combinatorial synthesis allows a chemist using solid phase techniques to prepare hun dreds of related compounds (called libraries) at a time It is one of the most active areas of organic synthesis especially m the pharmaceutical industry... 

The second method for mixture analysis is the use of specialized software together with spectral databases. We have developed a mixture analysis program AMIX for one- and multidimensional spectra. The most important present applications are the field of combinatorial chemistry and toxicity screening of medical preparations in the pharmaceutical industry. An important medical application is screening of newborn infants for inborn metabolic errors. 

Chapters 1 and 2 have been reorganised and updated in line with recent developments. A new chapter on the Future of Purification has been added. It outlines developments in syntheses on solid supports, combinatorial chemistry as well as the use of ionic liquids for chemical reactions and reactions in fluorous media. These technologies are becoming increasingly useful and popular so much so that many future commercially available substances will most probably be prepared using these procedures. Consequently, a knowledge of their basic principles will be helpful in many purification methods of the future. 

Combinatorial chemistry has played an increasing role in drug discovery. Wacker et al. extended the Madelung indole process successfully to solid phase library synthesis for the preparation of 2,3-disubstituted indoles. A number of examples follow in the table. 

Although the preparation of the quite complex selector modules prior to the synthesis of the library represented a rather significant synthetic effort, this study showed clearly the potential of combinatorial chemistry in the early development stage of a chiral separation medium and demonstrated a novel approach to rapid screening that might be amenable to full automation in the future. 

To speed the process of drug discovery, combinatorial chemistry> has been developed to prepare what are called combinatorial libraries, in which anywhere from a few dozen to several hundred thousand substances are prepared simultaneously. Among the early successes of combinatorial chemistry is the development of a benzodiazepine library, a class of aromatic compounds much used as antianxiety agents. 

Two main approaches to combinatorial chemistry are used—parallel synthesis and split synthesis. In parallel synthesis, each compound is prepared independently. Typically, a reactant is first linked to the surface of polymer beads, which are then placed into small wells on a 96-well glass plate. Programmable robotic instruments add different sequences of building blocks to tfie different wells, thereby making 96 different products. When the reaction sequences are complete, the polymer beads are washed and their products are released. 

Combinatorial chemistry (Chapter 16 Focus On) A procedure in which anywhere from a few dozen to several hundred thousand substances are prepared simultaneously. 

Combinatorial Chemistry. Figure 1 Whereas in classical chemical synthesis one target molecule was prepared in combinatorial chemistry the systematic combination of building blocks generates chemical libraries. 

Precisely defined collections of different chemical compounds are denominated as chemical libraries that can be efficiently prepared by methods of combinatorial chemistry. Each chemical compound owes specific structural, steiic, and electronic properties that determine all possible interactions of the small molecule with a given protein or receptor. The molecule s properties are based on the steiic arrangement of functional groups, including the conformations that can be attained by a specific structure. 

Combinatorial Chemistry. Figure 2 Chemical libraries are prepared either by parallel synthesis or by the split-and-recombine method. In the latter case, coupling m building blocks in m separated reaction flasks through n synthetic cycles on a beaded polymer carrier generates a combinatorial library with nf individual compounds and one compound per bead. 

The field of synthetic enzyme models encompasses attempts to prepare enzymelike functional macromolecules by chemical synthesis [30]. One particularly relevant approach to such enzyme mimics concerns dendrimers, which are treelike synthetic macromolecules with a globular shape similar to a folded protein, and useful in a range of applications including catalysis [31]. Peptide dendrimers, which, like proteins, are composed of amino acids, are particularly well suited as mimics for proteins and enzymes [32]. These dendrimers can be prepared using combinatorial chemistry methods on solid support [33], similar to those used in the context of catalyst and ligand discovery programs in chemistry [34]. Peptide dendrimers used multivalency effects at the dendrimer surface to trigger cooperativity between amino acids, as has been observed in various esterase enzyme models [35]. 

Due to the rising interest in supramolecular structures and nanoarchitectures, as well as their broad applicability, including the field of combinatorial chemistry, iterative strategies will gain more and more importance in preparative organic chemistry [60]. 

The preparation of resin-bound nitroalkenes via a microwave-assisted Knoevenagel reaction of resin-bound nitroacetic acid with aryl and alkyl substituted aldehydes is reported. The potential of these resin-bound nitroalkenes for application in combinatorial chemistry is demonstrated by a Diels-Alder reaction with 2,3-dimethylbutadiene (Scheme 8.9). It is also used for one-pot three-component tandem [4+2]/[3+2] reactions with ethyl vinyl ether and styrene 46... 

An intramolecular variant of the above chemistry has been used for the preparation of pyrroloindolizines. A -Allyl- and iV-propargyl-glyoxals react with tetrahydroisoquinoline to give 231 and 232, respectively (Equations 28 and 29). Furthermore, these reagents have been linked through the (V-substituent to a polymeric resin for further use in solid-phase and combinatorial chemistry <1997JA6153>. 

One of the cornerstones of combinatorial synthesis has been the development of solid-phase organic synthesis (SPOS) based on the original Merrifield method for peptide preparation [19]. Because transformations on insoluble polymer supports should enable chemical reactions to be driven to completion and enable simple product purification by filtration, combinatorial chemistry has been primarily performed by SPOS [19-23], Nonetheless, solid-phase synthesis has several shortcomings, because of the nature of heterogeneous reaction conditions. Nonlinear kinetic behavior, slow reaction, solvation problems, and degradation of the polymer support, because of the long reactions, are some of the problems typically experienced in SPOS. It is, therefore, not surprising that the first applications of microwave-assisted solid-phase synthesis were reported as early 1992 [24],... 

DNLM 1. Combinatorial Chemistry Techniques--methods. 2. Drug Design. 3. Pharmaceutical Preparations—analysis. 4. Technology, Pharmaceutical—methods. QV 744 H6366 2009]... 

Domino reactions present a modern approach in organic synthesis since they allow the preparation of complex molecules starting from simple substrate in a few steps and in many cases with high stereoselectivity. Moreover, as multi-component transformation they are highly suitable for combinatorial chemistry and give access to libraries of great diversity. 

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