Halogeno-, preparation

This preparation illustrates the ready formation of the thiazole ring by the condensation of an ot-halogeno-ketone and a thioamide. Thus chloroacetone, which may conveniently be represented in the enol form (I), condenses with thiourea (II) to give 2-amino-4-methylthiazolc (III). 

All possible dichloro- or dibromothiazoles are known. The 2.5-dihalogeno derivatives can be prepared from the 5-halogeno-2-aminothiazoles by diazotization/decomposition with CuCl or CuBr (3, 12, 13, 18, 75). The 5-halogeno-2-aminothiazoles can be easily prepared by halogenation of 2-aminothiazole (65, 76-79) 2,5-dibromothiazole can also be prepared by direct bromination of 2-bromothiazole (5). 

Some 2-halogeno-5-nitrothiazoles and 2-nitro-5-halogenothiazoles are known. 2-Halogeno-5-nitrothiazoles can be prepared by a Sandmeyer reaction from 2-amino-5-nitrothiazole (1, 85), while 2-nitro-5-halo-genothiazoles can be analogously prepared by decomposition of dia-zonium salts arising from 2-amino-5-halogenothiazoles in presence of nitrite anion (82, 84). 

Many 2-substituted 5-nitrothiazoles are prepared (by nucleophilic substitution reactions on 2-halogeno-5-nitrothiazoles) for use as biocides or for their biological activity (31, 91-95). 

Transhalogenation, or the replacement of one halogeno substituent by another, is of little interest as a reaction but of great preparative importance. Accordingly, it is discussed in Section 2.13.3.3.9/. 

Ring expansion of haloalkyloxiranes provides a simple two-step procedure for the preparation of azetidin-3-ols (Section 5.09.2.3.2(f)) which can be extended to include 3-substituted ethers and O-esters (79CRV331 p. 341). The availability of 3-hydroxyazetidines provides access to a variety of 3-substituted azetidines, including halogeno, amino and alkylthio derivatives, by further substitution reactions (Section 5.09.2.2.4). Photolysis of phenylacylamines has also found application in the formation of azetidin-3-ols (33). Not surprisingly, few 2-0-substituted azetidines are known. The 2-methoxyazetidine (57) has been produced by an internal displacement, where the internal amide ion is generated by nucleophilic addition to an imine. 

Af-Halogeno-, fV-nitroso- and hence fV-amino-azetidines have been prepared from azetidines by reaction with positive halogen reagents and nitrosating agents, respectively (Section 5.09.2.2.3). 

Alkyl-/l -pyrrolines (8, n = 1) and 2-alkyl-/l -piperideines (8, n = 2) are readily formed by the methods used to prepare y- and S-amino ketones (3-6). The reaction of corresponding halogeno ketones with ammonia belongs to the classical reactions of this type. 

Numerous tetrahedral halogeno complexes [T1" X4] (X = Cl, Br, I) have been prepared by reaction of quaternary ammonium or arsonium halides on TIX3 in nonaqueous solution, and octahedral complexes TI "X< ] (X = Cl, Br) are also well established. The binuclear complex Cs3[Tl2"Cl<)J is an important structural type which features two TlCls octahedra sharing a common face of 3 bridging Cl atoms (Fig. 7.9) the same binuclear complex structure is retained when Tl " is replaced by Ti ", V ", Cr " and Fe " and also in K3W2CIS and CssBiily, etc. 

The member of this class which has been studied most thoroughly is 2-benzylidene-4-methyl-5(2 )-oxazolone (57). This compound may be prepared by ring closure of either 3-bromo-2-phenylacetamido-propionic acid or A-(a-halophenylacetyl)alanine (56) [Eq. (30)]. These reactions presumably proceed via unstable halogeno-5(4IT)-oxazolones, which rapidly lose hydrogen halide. 

Halogeno compounds have been prepared by direct halogena-tion or by Sandmeyer reaction on 4-aminoisothiazoles. As expected from general considerations, a halogen atom in the 4-position is less reactive than one in the 5-position, but nitriles are obtained in good yield with cuprous cyanide at elevated temperatures. With butyllithium, lithiation occurs exclusively in the 5-position, and no evidence of halogen displacement has been obtained. ... 

Attempts to prepare selenazole derivatives were first described by Hofmann,2 a student of Hantzsch, in connection with investigations in the thiazole series. By reaction of selenobenzamide with a-halogeno compounds corresponding to the general reaction (2, R" = CeHg), he synthesized a series of 2-phenylselenazoles. In the same way, several... 

Note Even from the limited number of recent preparative results that follow, it is evident that the interannular activating effect of a 6/7-nitro group on a 2/3-halogeno substituent is appreciable and that the effect of an adjacent nitro group on a normally unreactive 5-, 6-, 7-, or 8-halogeno substituent is so substantial that aminolysis becomes a practical procedure. 

Many nitroquinoxalines have been prepared by primary synthesis (see Chapter 1), from halogeno quinoxalines (see Section 3.2.7), or by passenger introduction (e.g., on deoxidative alkylation of an M-oxide see Section 4.6.2.2). However, one major route and one minor preparative route remain, and they are illustrated in the following subsections. 

The main preparative routes to quinoxaline ketones have been discussed earlier by primary synthesis (Chapter 1), by extranuclear acylation of alkylquinoxalines (Section 2.2.4), by oxidation of appropriate alkylquinoxalines (also Section 2.2.4), by displacement of a halogeno substituent (Section 3.2.7), by oxidation of... 

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