Pharmacophores Substructures

Treatment of diethyl [2- " C]malonate with two equivalents of formamide and sodium ethoxide at elevated temperature provided 4,6-dihydro[5- C]pyrimidine 14021. which served as a key intermediate in the synthesis of 5-amino-4-iodo[5- C]pyrimidine and the corresponding dehalogenated species, both important pharmacophoric substructures in the design of new pharmacologically active drug candidates. ... 

The JME can also serve as a query input tool for structure databases by allowing creation of complex substructure queries (Figure 2-130), which are automatically translated into SMARTS [22]. With the help of simple HTML-format elements the creation of 3D structure queries is also possible, as were used in the 3D pharmacophore searches in the NCI database system [129]. Creation of reac-... 

The Web-based graphical user interface permits a choice from numerous criteria and the performance of rapid searches. This service, based on the chemistry information toolkit CACTVS, provides complex Boolean searches. Flexible substructure searches have also been implemented. Users can conduct 3D pharmacophore queries in up to 25 conformations pre-calculated for each compound. Numerous output formats as well as 2D and 3D visuaHzation options are supplied. It is possible to export search results in various forms and with choices for data contents in the exported files, for structure sets ranging in size from a single compound to the entire database. Additional information and down-loadable files (in various formats) can be obtained from this service. 

The search for structural fragments (substructures) is very important in medicinal chemistry, QSAR, spectroscopy, and many other fields in the process of perception of pharmacophore, chromophore, or other -phores. 

D substructure search is usually known as pharmacophore searching in QSAR. Generally speaking, there are two major approaches to it topological and chemical function queries. These two techniques are based on a slighfly different philosophy and usually provide different results [31]. 

Application of the CCM to small sets (n < 6) of enzyme inhibitors revealed correlations between the inhibitory activity and the chirality measure of the inhibitors, calculated by Eq. (26) for the entire structure or for the substructure that interacts with the enzyme (pharmacophore) [41], This was done for arylammonium inhibitors of trypsin, Di-dopamine receptor inhibitors, and organophosphate inhibitors of trypsin, acetylcholine esterase, and butyrylcholine esterase. Because the CCM values are equal for opposite enantiomers, the method had to be applied separately to the two families of enantiomers (R- and S-enantiomers). 

Mason JS, Morize 1, Menard PR, Cheney DL, Hulme C, Labaudiniere RF. New 4-point pharmacophore method for molecular similarity and diversity applications Overview of the method and applications, including a novel approach to the design of combinatorial libraries containing privileged substructures. I Med Chem 1999 42 3251-64. 

Historically, ligand structure-based design has been the most widely used approach to the design of target-directed chemical libraries. Methods that start from hits or leads are among the most diverse, ranging from 2D substructure search and similarity-based techniques to analysis of 3D pharmacophores and molecular interaction fields (Fig. 15.2). 

The term non-classical cannabinoids is applied to a group of bicyclic compounds identified by researchers at Pfizer in the 1980s [129], These compounds lack the pyran ring of the classical cannabinoids and the second phenolic hydroxyl group of the cannabidiols, resulting in a simplified substructure represented by CP 47,497 (192) [130, 131], The non-classical cannabinoids still retain the three main pharmacophoric elements described above for the classical cannabinoids and the SAR in these regions parallels that of the classical cannabinoids [132]. 

Van drie, J.H., Weininger, D., and Martin, Y.C. ALADDIN an integrated tool for computer-assisted molecular design and pharmacophore recognition from geometric, steric, and substructure searching of three-dimensional molecular structures./. Comput.-Aided Mol. Des. 1998, 3, 225-251. 

Mason JS, Morize I, Menard PR, Cheney DL, Huhne C, Labaudiniere RF. (1999) New 4-Point Pharmacophore Method for Molecular Similarity and Diversity Appheations Overview of the Method and Applications, including a Novel Approach to the Design of Combinatorial Libraries Containing Privileged Substructures. J. Med. Chem. 42 3251-3264. 

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