A-Halo ketones preparation

Among compounds other than simple alkyl halides a halo ketones and a halo esters have been employed as substrates m the Gabriel synthesis Alkyl p toluenesul fonate esters have also been used Because phthalimide can undergo only a single alkyl ation the formation of secondary and tertiary amines does not occur and the Gabriel synthesis is a valuable procedure for the laboratory preparation of primary amines... 

Various alkylating agents are used for the preparation of pyridazinyl alkyl sulfides. Methyl and ethyl iodides, dimethyl and diethyl sulfate, a-halo acids and esters, /3-halo acids and their derivatives, a-halo ketones, benzyl halides and substituted benzyl halides and other alkyl and heteroarylmethyl halides are most commonly used for this purpose. Another method is the addition of pyridazinethiones and pyridazinethiols to unsaturated compounds, such as 2,3(4//)-dihydropyran or 2,3(4//)-dihydrothiopyran, and to compounds with activated double bonds, such as acrylonitrile, acrylates and quinones. 

This approach has been most useful for the preparation of vinylogous a-halo ketones (see section II-H). 

Halogenation of the double bond usually prevents the satisfactory preparation of vinylogous a-halo ketones by direct reaction of unsaturated ketones with... 

The reductive elimination of halohydrins provides a means of introduction of double bonds in specific locations, particularly as the halohydrin may be obtained from the corresponding a-halo ketone. This route is one way of converting a ketone into an olefin. (The elimination of alcohols obtainable by reduction has been covered above, and other routes will be discussed in sections IX and X.) An advantage of this method is that it is unnecessary to separate the epimeric alcohols obtained on reduction of the a-bromo ketone, since both cis- and tran -bromohydrins give olefins (ref. 185, p. 251, 271 cf. ref. 272). Many examples of this approach have been recorded. (For recent examples, see ref. 176, 227, 228, 242, 273.) The preparation of an-drost-16-ene (123) is illustrative, although there are better routes to this compound. 

The imidazole nucleus is often found in biologically active molecules,3 and a large variety of methods have been employed for their synthesis.4 We recently needed to develop a more viable process for the preparation of kilogram quantities of 2,4-disubstituted imidazoles. The condensation of amidines, which are readily accessible from nitriles,5 with a-halo ketones has become a widely used method for the synthesis of 2,4-disubstituted imidazoles. A literature survey indicated that chloroform was the most commonly used solvent for this reaction.6 In addition to the use of a toxic solvent, yields of the reaction varied from poor to moderate, and column chromatography was often required for product isolation. Use of other solvents such as alcohols,7 DMF,8 and acetonitrile9 have also been utilized in this reaction, but yields are also frequently been reported as poor. 

In conclusion, a scaleable process for the preparation of 2,4-subsituted imidazole from amidines and a-halo ketones is described. This method avoids the use of chloroform as solvent and affords the desired products in consistently good to excellent yields. 

Primary amines can be prepared from alkyl halides by the use of hexamethylenetetramine followed by cleavage of the resulting salt with ethanolic HCl. The method, called the Delepine reaction, is most successful for active halides such as allylic and benzylic halides and a-halo ketones, and for primary... 

When diazo ketones are treated with HBr or HCl, they give the respective a-halo ketones, but HI does not give the reaction, since it reduces the product to a methyl ketone (10-87). a-Fluoro ketones can be prepared by addition of the diazo ketone to polyhydrogen fluoride-pyridine. This method is also successful for diazoalkanes. 

Among other methods for the preparation of alkylated ketones are (1) the Stork enamine reaction (12-18), (2) the acetoacetic ester synthesis (10-104), (3) alkylation of p-keto sulfones or sulfoxides (10-104), (4) acylation of CH3SOCH2 followed by reductive cleavage (10-119), (5) treatment of a-halo ketones with lithium dialkyl-copper reagents (10-94), and (6) treatment of a-halo ketones with trialkylboranes (10-109). 

Trialkylboranes react rapidly and in high yields with a-halo ketones,a-halo esters, a-halo nitriles, and a-halo sulfonyl derivatives (sulfones, sulfonic esters, sulfonamides) in the presence of a base to give, respectively, alkylated ketones, esters, nitriles, and sulfonyl derivatives. Potassium tert-butoxide is often a suitable base, but potassium 2,6-di-tert-butylphenoxide at 0°C in THF gives better results in most cases, possibly because the large bulk of the two tert-buXy groups prevents the base from coordinating with the R3B. The trialkylboranes are prepared by treatment of 3 mol of an alkene with 1 mol of BH3 (15-16). With appropriate boranes, the R group transferred to a-halo ketones, nitriles, and esters can be vinylic, or (for a-halo ketones and esters) aryl. " °... 

Thiazole and its derivatives are conventionally prepared from lachrymatory, a-halo-ketones and thioureas (or thioamides) by Hantzsch procedure [146]. In a marked improvement, Varma et al. have synthesized the title compounds by the simple reaction of in situ-generated a-tosyloxyketones, from arylmethyl ketones and [hydroxy(tosyl-oxy)iodo]benzene (HTIB), with thioamides in the presence of K 10 clay using micro-wave irradiation (Scheme 6.43) the process is solvent-free in both the steps [147]. 

Aqueous solutions of vanadous chloride (vanadium dichloride) are prepared by reduction of vanadium pentoxide with amalgamated zinc in hydrochloric acid [213], Reductions are carried out in solution in tetrahydrofuran at room temperature or under reflux. Vanadiiun dichloride reduces a-halo ketones to ketones [214], a-diketones to acyloins [215], quinones to hydroquinones [215], sulfoxides to sulfides [216] and azides to amines [217] (Procedure 40, p. 215). 

Russian authors investigated this important reaction type to prepare a wide range of aryl-, alkyl-, and acyl-substituted imidazo[2,l-ft]thiazoles (70KGS508, 70KGS512 71KGS389). Several 2-mercaptoimidazoles react with a-halo ketones in one step directly to the bicyclic products 35 under reflux in butanol or ethanol followed by basification. Yields vary between 52 and 99%, but the two-step cyclization route requires isolation of the intermediates 34 and subsequent heating in phosphorus oxychloride. 

The a-halo ketone has also been prepared in situ (NBS, benzoyl peroxide, light) [89IJC(B)500]. Similarly, imidazo[2,l-b][l,3,4]thiadiazoles are accessible from 2-amino-l,3,4-thiadiazoles and acetophenones in the presence of hydroxy(tosyloxy)iodobenzene (HTIB). This latter method has been proposed as more convenient and versatile than the reaction of 2-amino-1,3,4-thiadizoles with a-halo ketones [94IJC(B)686, 94JCR(S)38, 94MI5],... 

Mercaptotriazoles 133, available from thiosemicarbazones, are versatile starting materials for the preparation of thiazolo[3,2-h][l,2,4]triazoles. Treatment with a-halo ketones (and esters) yields S-alkylated derivatives that are cyclized to 134 either directly or on treatment with acidic catalysts (e.g., P2O5/H3PO4). 

The a-halo ketone compound has also been prepared in situ. Dimedone reacts with 2-mercaptotriazoles in the presence of bromine to give 150 (91H231). 

Alkylation of oxazolones with a-halo ketones under phase-transfer catalysis generated an enolate 155 from initial alkylation at C-4 that immediately translac-tonized to produce an enol lactone 156 (Scheme 7.46)." Selected examples of 5(47/)-oxazolones prepared via alkylation are shown in Table 7.17 (Fig. 7.19). 

Preparation of enamines, 409 Preparation of enol acetates, 411 Preparation of enol ethers, 409 Preparation of a-halo ketones, 267 Preparation of 3/3-hydroxyandrosta-5,15-dien-17-one, 302... 

The thiazole-2-thione (51) with an a-halo ketone gives the intermediate (52) which is cyclized by strong acid into the thiazolo[2,3-/ thiazolium salt (53) (77HC(30-i)l). A wide variety of [5,5]-fused systems are prepared in this way. 

Dithiobiurets react with a-halo ketones79-82 or aldehydes (generated in situ)63 to yield 2-thiureidothiazoles (40), which can be converted in two steps to 2-guanidinothiazoles.81 However, Beyer and Hantschel81 found that 2-guanidinothiazoles could be more conveniently prepared via the reaction of 1-amidino-2-thiourea with a-halo ketones or aldehydes. 

Various approaches have been used to prepare pyrroles on insoluble supports (Figure 15.1). These include the condensation of a-halo ketones or nitroalkenes with enamines (Hantzsch pyrrole synthesis) and the decarboxylative condensation of N-acyl a-amino acids with alkynes (Table 15.3). The enamines required for the Hanztsch pyrrole synthesis are obtained by treating support-bound acetoacetamides with primary aliphatic amines. Unfortunately, 3-keto amides other than acetoacetamides are not readily accessible this imposes some limitations on the range of substituents that may be incorporated into the products. Pyrroles have also been prepared by the treatment of polystyrene-bound vinylsulfones with isonitriles such as Tosmic [28] and by the reaction of resin-bound sulfonic esters of a-hydroxy ketones with enamines [29]. 

Support-bound alkylating agents have been used to N-alkylate pyridines and dihydropyridines (Entries 7 and 8, Table 15.21). Similarly, resin-bound pyridines can be N-alkylated by treatment with a-halo ketones (DMF, 45 °C, 1 h [267]) or other alkylating agents [246]. Polystyrene-bound l-[(alkoxycarbonyl)methyl]pyridinium salts can be prepared by N-alkylating pyridine with immobilized haloacetates (Entry 8, Table 15.21). These pyridinium salts react with acceptor-substituted alkenes to yield cyclopropanes (Section 5.1.3.6). Pyridinium salts have also been prepared by reaction of resin-bound primary amines with /V-(2,4-dinitrophenyl)pyridinium salts [268,269]. 

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