Parent compound preparation

For example, van Heek and coworkers observed a lead candidate that underwent extensive first-pass metabolism and yet elicited a significant level of pharmacological activity (van Heek et al., 1997). To evaluate the biological activity of the in vivo biotransformation products, they collected samples of bile from rats dosed with a lead compound and directly administered the samples to a bile duct cannulated rats via an intraduodenal cannula. As a control study, the parent compound prepared in a blank bile was dosed in a similar fashion to the recipient rats. The results indicated that the in vivo activity elicited by the bile samples was higher than the parent control sample, clearly indicating the presence of an active metabolite(s) that was more potent than the parent compound. To identify the active component, the bile sample was then fractionated and each fraction tested for biological activity. The structure of the metabolite was then established following the detection of the active fraction. As mentioned before, further modification of the active metabolite led to the discovery of ezetimibe. 

Two compounds are selected from the derivatives near the parent compound, prepared, and tested. These are chosen following the Topliss approach [10] that is, by looking for points where one of the parameters is systematically increased or decreased with respect to the original substance, the other remaining constant as far as possible. 

Whereas the unsubstituted parent compounds prepared by Jenny et al. (Section 2.2.1) were not considered likely to be able to act as ligands or hosts, some indications of the capacity of a//-homocalixarenes and -calixpyridines to bind to guests are given by the results of X-ray structure analyses. The cluster type inclusion of water by the pentameric pyridine macrocycle 38 via hydrogen bonds seems... 

Hofmann (1), of the Zurich School, was the first to have tried unsuccessfully to prepare the unsubstituted parent compound, selenazole much later, in 1955, Metzger and Bailly (2) were equally unsuccessful in trying to prepare selenazole from 2-aminoselenazole by reduction of the diazo compound,... 

Historically, the discovery of one effective herbicide has led quickly to the preparation and screening of a family of imitative chemicals (3). Herbicide developers have traditionally used combinations of experience, art-based approaches, and intuitive appHcations of classical stmcture—activity relationships to imitate, increase, or make more selective the activity of the parent compound. This trial-and-error process depends on the costs and availabiUties of appropriate starting materials, ease of synthesis of usually inactive intermediates, and alterations of parent compound chemical properties by stepwise addition of substituents that have been effective in the development of other pesticides, eg, halogens or substituted amino groups. The reason a particular imitative compound works is seldom understood, and other pesticidal appHcations are not readily predictable. Novices in this traditional, quite random, process requite several years of training and experience in order to function productively. 

Synthesis. The parent compound, bora2iae [6569-51-3] is best prepared by a two-step process involving formation of B-trichlorobora2iQe followed by reduction with sodium borohydride. These reactions have been studied ia some detail (96). 

Numerous fluorinated and perfluorinated alkyl hypochlorites have been synthesized and characterized, eg, CF OCl [22082-78-6] C2F OCl [22675-67-8] /-C F OCl [22675-68-9] and /-C F OCl [22082-78-6]. These nonmetal oxychlorine compounds are much more thermally stable than the corresponding parent compounds and can be prepared by reaction of GIF with the appropriate carbonyl compound or alcohol. 

Hydroxyphthalazin-l(2//)-one is obtained in a smooth reaction between phthalic anhydride and hydrazine hydrate and this is again the starting compound for many 1-substituted and/or 1,4-disubstituted phthalazines. The transformations of 1,4-dichloro-phthalazine, which is prepared in the usual manner, follow a similar pattern as shown for pyridazines in Scheme 110. On the other hand, phthalonitrile is the preferential starting compound for amino- and hydrazino-phthalazines. The most satisfactory synthesis of phthalazine is the reaction between a,a,a, a -tetrachloro-o-xylene and hydrazine sulfate in sulfuric acid (67FRP1438827), alt iough catalytic dehalogenation of 1-chloro- or 1,4-dichloro-phthalazine or oxidation of 1-hydrazinophthalazine also provides the parent compound in moderate yield. 

Dicyano-l,2,3-trithiole 2-oxide (143) has been prepared from the silver salt of 2,3-dimercaptomaleonitrile (142) and thionyl chloride (66HC(2l-i)67). Similarly, the reaction of ethylene glycol (144) with thionyl chloride gave 1,3,2-dioxathiolane 2-oxide (145), the parent compound of saturated five-membered cyclic sulfites (see Chapter 4.33). 

The first simple thiirane fused to a saturated four-membered ring is (13), prepared in 34% yield by irradiation of the acyclic sulfide (12) (69JOC896). The parent compound is not known. 

First heterocyclic aromatic analogue of pyridine (Ph3C5H2P) prepared by G. MUrkl, followed by the parent compound C3H3P in 1971 (A. J. Ashe). 

Structure-activity studies of 5,6,7,8-tetrahdyro-5,5,8,8-tetramethyl-2-quinoxaline derivatives necessitated the preparation of thiophene-containing compound 17. Stetter conditions using thiazolium salt 20 as catalyst resulted in the preparation of 1,4-diketone 21 from 18 and 19. Condensation of 21 with phosphorus pentasulfide followed by saponification resulted in 17. In this fashion, the authors replaced the amide linker of parent compound 22 with the rigid thiophene moiety. 

It will be observed that most syntheses yield pyrylium salts in which positions 2,4, and 6 are substituted. Since according to formulas Ib-lc these positions have a partial positive charge, it can readily be understood why electron-donating substituents (hydroxy, alkoxy, alkyl, or aryl) in these positions stabilize the pyrylium salts. Only three pyrylium salts which do not have substituents in either a-position have been reported and few unsubstituted in y or in one a-position they are less stable toward hydrolysis, and in the case of perchlorates they explode more easily, than 2,4,6-trisubstituted compounds. In fact, the former are secondary, the latter tertiary carbonium ions. This fact also explains why the parent compound (1) was prepared only in 1953. 

Dihydro-j8-carboline itself, the parent compound of the group, whose original preparation from A -formyltryptamine was doubtful, has now been describedand characterized. Its 9-methyl and 6-methoxy derivatives have also been prepared. 

The first example of an indolo[2,3-a]carbazole derivative reported with a reasonably estabhshed structure was the mono N-methylated system 9, prepared via dehydrogenation with palladium on charcoal of the octahydro derivative 10, available via reaction of the aminocarbazole 11 with 2-hydroxycyclohexanone in the presence of a trace amount of anihnium bromide (Scheme 1). An approach toward the parent compound 1 using the same method has also been attempted, although without success (56JCS4783). The utility of this route is impaired by the complexity of the starting material, which requires multistep preparation, and the harsh conditions of the final step. 

The popularity of aspirin has led to the preparation of a liost of relatively simple derivatives in the hope of finding a ilrug that would be either superior in action or better tolerated. i alicylamide (5), for example, is sometimes prescribed for pa-I Lents allergic to aspirin. It should be noted, however, that I his agent is not as active as the parent compound as an antiinflammatory or analgesic agent. This may be related to the fact I hat salicylamide does not undergo conversion to salicylic acid i 11 the body. 

It was known for some time that even after the corticoids had been separated from crude extracts of the adrenal cortex, the remaining material, the so-called "amorphous fraction" still possessed considerable mineralocorticoid activity. Aldosterone (250), one of the last steroids to be isolated from this fraction, proved to be the active principle. This compound proved to be an extremely potent agent for the retention of salt, and thus water, in body fluids. An antagonist would be expected to act as a diuretic in those edematous states caused by excess sodium retention. Although aldosterone has been prepared by both total and partial synthesis, the complexity of the molecule discouraged attempts to prepare antagonists based directly on the parent compound. 

In an effort to more closely mimic the aromatic substitution pattern found in morphine (see A) the pethidine analog containing the m-hydroxy group was prepared as well. Thus, in a synthesis analogous to that used to prepare the parent compound, double alkylation of m-methoxyphenylacetonitrile with the chloroamine. 

The free acid analogue of the antipsoriatic agent etretinate (103) is prepared in substantially the same way as the parent compound. Thus, the aldehyde group in 98 is converted finally to the pho.sphonate (101) by sequential reduction (99), conversion to the chloride (100), and finally reaction with triethyl phosphite. Condensation of the ylide from 101 with the benzaldehyde 102 gives etretinate (103) saponification affords acitretin (104) [25]. 

Diazotization of biphenyl-2,2 -diamine, followed by treatment with aqueous ammonia, gives the parent compound la.331 A number of analogs lb-d, prepared in the same way. are all unstable oils.331... 

This class of aziridine-forming reaction includes the first reaction reported to afford aziridines. In 1888 Gabriel reported that aziridines could be prepared in a two-step process, by chlorination of ethanolamines with thionyl chloride, followed by alkali-induced cyclization [75]. Wenker subsequently reported that heating of 600 g of ethanolamine with more than 1 kg of 96 % sulfuric acid at high temperature produced P-aminoethyl sulphuric acid 282 g of it was distilled from aqueous base to give 23 g of aziridine itself, the first preparation of the parent compound in a pure condition [76]. Though there is no evidence to substantiate the hypothesis, the intermediate in these reactions is perhaps a cyclic sulfamidate (Scheme 4.51). 

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